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Periprocedural management of antithrombotic therapy in hospitalized patients

The periprocedural management of antithrombotic medications is a common challenge for hospitalists, for which there is limited high‐quality evidence to guide clinical decision making. The introduction of third‐generation antiplatelet agents (prasugrel and ticagrelor) and the new oral anticoagulants (rivaroxaban, apixaban, and dabigatran), has added an additional layer of complexity to clinical management.

This article will provide a conceptual framework for the periprocedural management of antithrombotic therapy, with a particular focus on procedures that are considered core competencies by the Society of Hospital Medicine; these include: arthrocentesis, lumbar puncture, paracentesis, thoracentesis, and central line placement (Table 1).[1, 2] The recommendations in this article are based on a review of published guidelines and consensus statements and their supporting literature.[3, 4, 5, 6, 7, 8] Additional articles were identified by performing a PubMed keyword search using the terms perioperative management or periprocedural management and anticoagulation or antithrombotic or antiplatelet in combination with keywords relevant to the content areas (eg, arthrocentesis, lumbar puncture). Articles for inclusion were chosen based on methodological quality and relevance to hospital medicine.

There are several questions that must be addressed when developing a periprocedural antithrombotic management strategy:

  1. What is the patient's risk of bleeding if antithrombotic therapy is continued?
  2. What is the patient's risk of thromboembolism if antithrombotic therapy is interrupted?
  3. Are there interventions that can decrease the risk of periprocedural bleeding and/or thromboembolism?

WHAT IS THE PATIENT'S RISK OF BLEEDING IF ANTITHROMBOTIC THERAPY IS CONTINUED?

Although the risk of bleeding is well described for many procedures, there are limited data on how that risk is affected by coagulopathy in general and antithrombotic medications in particular. When these data are available, they are largely derived from case series or bridging registries, which include heterogeneous patient populations and nonstandardized definitions of bleeding.[8, 9, 10] As such, few procedural or surgical professional societies have published guidelines on the periprocedural management of antithrombotic therapy,[3, 4, 5, 11]and guidelines from the American College of Chest Physicians (ACCP), the American College of Cardiology (ACC), and American Heart Association (AHA) only provide specific recommendations regarding minor ambulatory procedures.[6, 7, 8]

Procedures can be categorized as low or high risk for bleeding based on the following considerations: the extent of associated tissue injury, proximity to vital organs or vascular structures, the ability to readily detect and control bleeding, and the morbidity associated with a bleeding complication (eg, a small bleed into the epidural space is potentially catastrophic, whereas a large bleed from the colon often results in no permanent harm). For procedures with a high risk or consequence of bleeding, anticoagulants must be stopped, whereas in some cases antiplatelet agents can be safely continued. For procedures with a low risk or consequence of bleeding, it may be possible to continue both anticoagulant and antiplatelet agents.

Recommended Periprocedural Management of Antithrombotic Therapy
Procedure Antithrombotic Therapy
Aspirin Thienopyridines Prophylactic UFH or LWMH Therapeutic UFH or LMWH Warfarin NOACs
  • NOTE:+= safe to continue during procedure;= unsafe to continue during procedure;= insufficient data, individualized approach recommended. Abbreviations: BID, twice daily; LMWH, low‐molecular‐weight heparin; NOACs, new oral anticoagulants (rivaroxaban, apixiban, dabigatran); UFH, unfractionated heparin.

Arthrocentesis[12, 13, 14, 15] + + + + + +
Lumbar puncture[3] + 5000 units UFH BID
Paracentesis[28, 29, 30] + + +
Thoracentesis[37, 38, 39, 40, 41, 42] + + +
Central venous catheter insertion[48, 49, 50, 51, 52, 53] + + +

Because procedures in hospitalized patients are most often performed for the purpose of diagnosing or treating an emergent condition, the risk of delaying the procedure while antithrombotic medications are held must be part of the overall risk‐benefit calculation.

Arthrocentesis

Bleeding complications from arthrocentesis are very rare, and there are few data on the additional risk associated with antithrombotic therapy.[12, 13, 14] In a retrospective cohort study, investigators determined the incidence of clinically significant bleeding (defined as bleeding requiring reversal of anticoagulation, prolonged manual pressure, surgical intervention, hospital admission, or delay in hospital discharge) and procedure‐related pain among 514 patients on antithrombotic therapy referred for arthrocentesis or injection of the hip, shoulder, or knee. Four hundred fifty‐six procedures were performed in patients without interrupting warfarin therapy, all of whom maintained an international normalized ratio (INR)2, and 184 procedures were performed in patients who had stopped their warfarin to achieve an INR <2. Antiplatelet therapy was routinely continued in both groups, with 48% of patients taking aspirin and 9% clopidogrel. There was 1 bleeding complication (0.2%) in a patient with an INR of 2.3 who was also taking aspirin, and 2 patients developed procedure‐related pain (INR 3.3 and 5.3, neither taking antiplatelet medications).[15]

Based on the available evidence, arthrocentesis appears to be safe in patients on therapeutic warfarin, with or without aspirin and/or clopidogrel. At present, there are no published studies that address the risk of arthrocentesis in patients taking other antiplatelet or anticoagulant medications, but given the low overall risk of this procedure, it is reasonable to infer that these medications can also be safely continued.

Lumbar Puncture

The incidence of bleeding complications from diagnostic lumbar puncture is unknown, but is likely similar to that seen with spinal anesthesia, where in a large retrospective observational study, spinal hematoma occurred in 1:165,000 spinal block procedures.[16] Factors associated with an increased risk of spinal hematoma include traumatic tap, advanced age, female gender, spinal cord or vertebral column abnormalities, coagulopathy, and not allowing sufficient time between stopping and restarting antithrombotic therapy.[3, 17, 18, 19, 20]

Therapeutic anticoagulation must be stopped and prophylactic anticoagulation delayed before performing a lumbar puncture. The 1 exception is low‐dose unfractionated heparin (UFH), which the American Society for Regional Anesthesia (ARSA) recommends continuing in patients undergoing neuraxial procedures, provided the total dose is 5000 U twice daily. This assessment is based on observational data, surveys of practice patterns, and decades of use without evidence of complications; in fact, there are only 5 case reports of spinal hematomas in this population.[3] However, because these data are from surgical populations, in which heparin thromboprophylaxis is typically dosed at 5000 units twice daily, there are limited data on the safety of higher or more frequent doses of heparin. In a retrospective cohort study of 928 patients who received thoracic epidural analgesia in conjunction with UFH dosed at 5000 U, 3 times daily, there were no cases of neuraxial bleeding, but given the rarity of neuraxial hematoma, it is not possible to draw any conclusions from this relatively small sample size.[21]

In November 2013, based on surveillance data showing increased risk for spinal or epidural hematoma associated with low‐molecular‐weight heparin (LMWH), the US Food and Drug Administration (FDA) issued a drug safety communication recommending that neuraxial procedures be delayed for 12 hours after prophylactic LMWH and 24 hours after therapeutic LMWH, and that LMWH not be restarted for at least 4 hours after catheter removal.[20] These recommendations are largely consistent with existing guidelines[3, 22] but are not explicitly stated in the package insert for any of the LMWHs available in the United States,[23, 24, 25] and the FDA is working with the manufacturers to add this information.

Nonsteroidal anti‐inflammatory drugs (NSAIDs), dipyridamole, and aspirin do not appear to increase the risk of spinal hematoma and are considered safe to continue.[11, 26] There are limited data on the safety of thienopyridine medications in neuraxial anesthesia, but based on case reports and increased bleeding rates seen in surgical populations, it is generally recommended that these medications be discontinued before performing a lumbar puncture.[3, 22, 27]

The optimal time to restart anticoagulation after a lumbar puncture is unknown. The ARSA recommends a minimum of 1 hour for UFH and 2 hours for LMWH after neuraxial catheter removal, and provides no specific guidance about other anticoagulants,[3] whereas the European Society of Anesthesiology recommends a minimum of 1 hour for UFH, 4 hours for LMWH, 4 to 6 hours for rivaroxaban and apixiban, and 6 hours for dabigatran and fondaparinux.[22] Longer time periods should be considered after a traumatic tap, and postprocedure monitoring of neurological function is recommended for all patients.

The available evidence suggests that lumbar puncture can be safely performed in patients being treated with aspirin, NSAIDs, and UFH dosed at 5000 U twice daily; the safety of higher or more frequent doses of UFH is not known. Lumbar puncture should be delayed 12 hours after prophylactic LMWH and 24 hours after therapeutic LMWH, and LMWH should not be restarted for at least 4 hours after the procedure.[20] There are limited data on the safety of thienopyridines, but they should generally be discontinued, and all other prophylactic or therapeutic anticoagulation must be stopped prior to the procedure.

Paracentesis

Bleeding complications from paracentesis are uncommon, with abdominal wall hematoma and hemoperitoneum complicating 1% and 0.01% of procedures, respectively.[28, 29, 30] Whether antithrombotic therapy increases the risk of bleeding during paracentesis is unknown, primarily because most patients for whom the procedure is indicated have coagulopathy and thrombocytopenia from liver disease, and are therefore rarely treated with these medications.

Although patients with liver disease often have an elevated INR due to impaired hepatic synthesis of clotting factors, it is incorrect to generalize the observed rate of bleeding in this population to patients with an elevated INR from warfarin therapy who may require paracentesis for reasons unrelated to liver disease (eg, malignancy or infection). The coagulopathy of liver disease reflects deficiencies in the hepatic production of both pro‐ and anticoagulant proteins, and these patients develop both thrombotic and hemorrhagic complications irrespective of their in vitro coagulation indices.[31]

Although the available evidence suggests that paracentesis can be safely performed in patients with coagulopathy from liver disease, regardless of the INR,[30] little is known about the bleeding risk in other patients, with or without antithrombotic therapy. Based on indirect evidence, it is reasonable to assume that prophylactic UFH or LWMH or antiplatelet therapy would confer minimal additional risk, whereas the safety of continuing therapeutic anticoagulation is unknown.

Thoracentesis

Bleeding complications from thoracentesis are uncommon, generally occurring in <1% of procedures.[32, 33, 34] Factors associated with increased risk of overall complications include operator inexperience, large volume drainage, and lack of ultrasound guidance.[34, 35, 36] There are no studies that specifically address the risk of bleeding in patients on anticoagulant therapy, but such patients are included in studies on the risk of bleeding with coagulopathy.[37, 38, 39, 40]

In a retrospective cohort study of 1076 ultrasound‐guided thoracenteses performed by radiologists on patients with coagulopathy (defined as thrombocytopenia or an elevated INR from any cause), there were no bleeding complications (defined as anything other than minimal symptoms not requiring intervention). Among the patients in this study, 497 (46%) patients had a preprocedure INR >1.5; 198 (24%) had an INR between 2 and 3, and 32 (4%) had an INR >3.[39]

A similar study, which compared outcomes in patients with corrected and uncorrected coagulopathy, included 744 patients with an INR >1.6 (from any cause), of which 167 received preprocedural fresh‐frozen plasma (FFP) and 577 did not. There was 1 (0.1%) bleeding complication in a patient who received prophylactic FFP and none in the group that was not transfused.[38]

In a prospective cohort of 312 patients at increased risk for bleeding (from coagulopathy or antithrombotic medications) who underwent ultrasound‐guided thoracentesis by a pulmonologist or physician's assistant, 44 (34%) had an INR >1.5 (secondary to liver disease or warfarin therapy), 15 (12%) were taking clopidogrel, and 14 (11%) were treated with therapeutic LMWH within 12 hours or therapeutic UFH within 4.5 hours of the procedure. There were no bleeding complications in any of the patients (defined as mean change in hematocrit, chest x‐ray abnormalities, hemothorax, or requirement for transfusion).[37]

Although there are no studies that specifically address the use of aspirin and bleeding complications in thoracentesis, it is generally considered safe to continue this medication,[5] and there are small studies that show that thoracentesis and small‐bore chest tubes can be safely placed in patients taking clopidogrel.[41, 42]

Thoracentesis is associated with a low rate of bleeding complications, and when performed by an experienced operator using ultrasound, warfarin does not appear to increase this risk. However, given the low overall complication rate, it is not known whether patients on warfarin would have worse outcomes in the event of more serious complications (eg, intercostal artery laceration). At present, there are no published studies that address the risk of thoracentesis in patients taking new oral anticoagulants (NOACs).

Central Venous Catheter Insertion

The incidence of bleeding complications from central venous catheter (CVC) placement varies depending on the site of insertion and definition of bleeding, with hematoma and hemothorax occurring in 0.1% to 6.9%, and 0.4% to 1.3% of procedures, respectively.[43, 44, 45] Factors that increase the likelihood of complications include operator inexperience, multiple needle passes, and lack of ultrasound guidance.[46, 47] There are no studies that specifically address the risk of bleeding from CVC placement in patients on anticoagulant therapy, but such patients are included in studies of CVC placement in patients with coagulopathy, which report similar complication rates as seen in patients with normal hemostasis.[48, 49, 50, 51, 52, 53]

In a retrospective cohort study, investigators collected information on CVC‐associated bleeding complications in 281 medical and surgical intensive care patients with coagulopathy (INR 1.5 from any cause) after they adopted a more conservative approach to plasma transfusion in their intensive care unit; specifically, the routine use of prophylactic FFP to correct coagulopathy was discouraged for patients with an INR <3 (vs usual practice using an INR cutoff of 1.5), but the final decision was left to the discretion of the attending performing or supervising the procedure. Bleeding was defined as insertion‐site hematoma, interventions other than local manual pressure, and the need for blood transfusion. One case of bleeding (hematoma) was observed in a patient with an INR of 3.9, who received FFP before the procedure. There were no complications among those with uncorrected coagulopathy, including 66 patients with an INR between 1.5 and 2.9, and 6 with an INR 3.0. Ultrasound guidance was used in 50% of CVCs placed in the internal jugular vein.[54]

Although there are no studies that specifically address the use of antiplatelet drugs and bleeding complications in CVC placement, aspirin is generally considered safe to continue,[5] and by inference, thienopyridines are expected to add minimal additional risk.

CVC placement is associated with a variable rate of bleeding complications, with hematoma being relatively common. Based on the available literature, warfarin does not appear to increase this risk, but there are limited data from which to draw firm conclusions. A femoral or jugular approach may be preferable because they allow for ultrasound visualization and are amenable to manual compression. There are no published studies that address the risk of CVC placement in patients taking NOACs, and although the risk of bleeding is probably similar to patients receiving warfarin, the lack of effective reversal agents for these medications should be part of any risk‐benefit calculation.[55]

WHAT IS THE PATIENT'S RISK OF THROMBOEMBOLISM IF ANTITHROMBOTIC THERAPY IS INTERRUPTED?

Anticoagulants

If it is determined that a procedure cannot safely be performed while continuing antithrombotic therapy, one must then consider the patient's risk of thromboembolism if these therapies are temporarily interrupted. Unfortunately, there are few robust clinical studies from which to make this assessment, and therefore most clinicians rely on the risk stratification model proposed by the ACCP, which divides patients into 3 tiers (low, moderate, high), based on their indication for anticoagulation and risk factors for thromboembolism (Table 2)[8]. The ACCP model is largely based on indirect evidence from antithrombotic therapy trials in nonoperative patients, and its application to perioperative patients necessitates several assumptions that may not hold true in practice.

American College of Chest Physicians Stratification for Perioperative Thromboembolism
Indication for Anticoagulant Therapy
Risk Stratum Mechanical Heart Valve Atrial Fibrillation VTE
  • NOTE: Abbreviations: CHADS2=congestive heart failure, hypertension, age 75 years, diabetes mellitus, and stroke or transient ischemic attack; TIA, transient ischemic attack; VKA, vitamin K antagonist; VTE, venous thromboembolism.

  • High‐risk patients may also include those with a prior stroke or TIA occurring >3 months before the planned surgery and a CHADS2 score <5, those with prior thromboembolism during temporary interruption of VKAs, or those undergoing certain types of surgery associated with an increased risk for stroke or other thromboembolism (eg, cardiac valve replacement, carotid endarterectomy, major vascular surgery).

High Thrombotic Risk
  • Any mitral valve prosthesis
  • Any caged‐ball or tilting disc aortic valve prosthesis
  • Recent (within 6 months) stroke or TIA
  • CHADS2 score of 5 or 6
  • Recent (within 3 months) stroke or TIA
  • Rheumatic valvular heart disease
  • Recent (within 3 months) VTE
  • Severe thrombophilia (eg, deficiency of protein C, protein S, or antithrombin; antiphospholipid antibodies; multiple abnormalities)
Moderate Thrombotic Risk
  • Bileaflet aortic valve prosthesis with one or more of the following risk factors: atrial fibrillation, prior stroke or TIA, hypertension, diabetes, congestive heart failure, age 75 years
  • CHADS2 score of 3 or 4
  • VTE within the past 3 to 12 months
  • Nonsevere thrombophilia (eg, heterozygous factor V Leiden or prothrombin gene mutation)
  • Recurrent VTE
  • Active cancer (treated within six months or palliative)
Low Thrombotic Risk
  • Bileaflet aortic valve prosthesis without atrial fibrillation and no other risk factors for stroke
  • CHADS2 score of 0 to 2 (assuming no prior stroke or TIA)
  • VTE >12 months previous and no other risk factors

First, it assumes that the annualized risk of a thrombotic event in nonoperative patients can be prorated to determine the short‐term risk of discontinuing antithrombotic therapy in the perioperative period. For example, it has been estimated that the risk for perioperative stroke in a patient with atrial fibrillation who temporarily interrupts anticoagulation for 1 week would be 0.1% (5% per year 52 weeks),[56, 57]and yet we know from observational data that the actual risk of perioperative stroke in similar patients is 5 to 7 times higher.[58, 59] Second, it assumes that bridging therapy will decrease the risk of thromboembolism in high‐risk patients when warfarin therapy is interrupted, a premise that is logical but has not been subject to randomized controlled trials.[60] Third, it does not take into account the surgery‐specific risk for thromboembolism, which varies significantly, with arterial thromboembolism being more common in cardiac valve, vascular, and neurologic procedures, and venous thromboembolism (VTE) being more likely in orthopedic, trauma, and cancer surgery.[61, 62] These limitations notwithstanding, the ACCP model still offers the best available framework for thrombotic risk assessment and a reasonable starting point for clinical decision making.

Antiplatelet Agents

Patients with coronary artery stents who undergo noncardiac surgery are at increased risk for adverse cardiovascular events, including acute stent thrombosis, which carries a risk of myocardial infarction and death of 70% and 30%, respectively.[63] This risk is highest during the period between stent implantation and endothelialization, a process that takes 4 to 6 weeks for bare‐metal stents (BMS) and 6 to 12 months for drug‐eluting stents (DES). Premature discontinuation of dual antiplatelet therapy is the most important risk factor for stent thrombosis during this time.[64] Although the optimal perioperative strategy for these patients is unknown, there is general agreement that elective surgery should be delayed for at least 4 weeks in patients with a BMS and 12 months for patients with a DES. If a procedure or surgery is required during this time period, every effort should be made to continue dual antiplatelet therapy; if this is not possible, aspirin should be continued, and thienopyridine therapy should be interrupted as briefly as possible (Table 3).

Recommended Timing for Periprocedural Interruption and Initiation of Antithrombotic Therapy
Recommended Interval Between Last Dose of Medication and Procedure Recommended Interval Between Procedure and First Dose of Medication, h
Low Risk or Consequence of Postprocedure Bleeding High Risk or Consequence of Postprocedure Bleeding
  • NOTE: Abbreviations: CrCl, creatinine clearance; LMWH, low‐molecular‐weight heparin; UFH, unfractionated heparin.

  • Assuming minimal platelet effect by 7 days and no effect by 10 days for (irreversible) agents: aspirin, ticlodipine, clopidogrel, and prasugrel. Ticlodipine drug clearance is prolonged by an additional 4 days after repeated dosing.

  • Ticagrelor and cilostazol half‐life depends on rate of drug clearance.

  • Five days is sufficient for cardiac surgery.[94]

  • Seven days per manufacturer[91]; drug effect may persist up to 10 days.

  • Five days per manufacturer[93]; a shorter interval is expected based on half‐life.

  • Intervals based on 45 drug half‐lives to achieve minimal residual anticoagulant effect; shorter intervals may be appropriate for procedures with low risk or consequence of bleeding. Adapted from Spyropoulos and Douketis.[95]

  • More than 90% of patients will achieve an international normalized ratio <1.5 after skipping 5 doses.[8]

  • Longer intervals are recommended for patients with CrCl <30 mL/min.[96]

  • Longer intervals are recommended for patients with CrCl <50 mL/min.[96]

  • Patients receiving dabigatran 75 mg twice daily.

  • Patients receiving rivaroxaban 15 mg daily.

Antiplatelet Medicationsa
Aspirin (81325 mg dailydipyridamole) 710 days (skip 69 doses) 24 48
Ticlodipine (250 mg twice daily) 1014 days (skip 1926 doses) 24 48
Clopidogrel (75 mg once daily) 710 days (skip 69 doses)b 24 48
Prasugrel (10 mg once daily) 710 days (skip 69 dose)c 24 48
Ticagrelor (90 mg twice daily; t =8 hours) 5 days (skip 8 doses) 24 48
Cilostazol (100 mg twice daily; t =11 hours) 3 days (skip 4 doses) 24 48
Anticoagulant Medicationse
Warfarin (t =3642 hours, but highly variable) 6 days (skip 5 doses)f 12 24
Intravenous UFH (t 60 minutes) 46 hours 24 4872
LMWH (t =37 hours)
Prophylactic dosing 12 hours# 12 2436
Therapeutic dosing
Once daily 24 hours (give 50% of last total dose)# 24 4872
Twice daily 24 hours (skip 1 dose)# 24 4872
Fondaparinux (t =17 hours, any dose) 34 days (skip 23 doses)h 24 4872
Dabigatran (150 mg twice daily)
CrCl>50 mL/min (t =1417 hours) 3 days (skip 4 doses) 24 4872
CrCl 3050 mL/min (t =1618 hours) 45 days (skip 68 doses) 24 4872
CrCl 1530 mL/min (t =1618 hours)i 45 days (skip 68 doses) 24 4872
Rivaroxaban (20 mg once daily)
CrCl>50 mL/min (t =89 hours) 3 days (skip 2 doses) 24 4872
CrCl 3050 mL/min (t =9 hours) 3 days (skip 2 doses) 24 4872
CrCl 1529.9 mL/min (t =910 hours)j 4 days (skip 3 doses) 24 4872
Apixiban (5 mg twice daily)
CrCl>50 mL/min (t =78 hours) 3 days (skip 4 doses) 24 4872
CrCl 3050 mL/min (t =1718 hours) 4 days (skip 6 doses) 24 4872

ARE THERE INTERVENTIONS THAT CAN DECREASE THE RISK OF PERIPROCEDURAL BLEEDING AND/OR THROMBOEMBOLISM?

Mitigating the Risk of Bleeding

Bleeding complications can be reduced by allowing a sufficient time for the effects of antithrombotic medications to wear off before performing a procedure. This requires an understanding of the pharmacology of these medications, with particular attention to patients in whom these medications are less well studied, including the elderly, patients with renal insufficiency, and those with very high or low body mass index. Table 3 provides recommendations for when to stop antithrombotic therapy prior to an invasive procedure. The intervals are based on the time needed to achieve a minimal antithrombotic effect, which is generally 4 to 5 half‐lives for anticoagulants and 7 to 10 days for irreversible antiplatelet agents. Shorter intervals may be appropriate for procedures with low risk or consequence of bleeding, but there are insufficient data to make specific recommendations regarding this strategy.

It is equally important to ensure that there is adequate time for postoperative hemostasis prior to restarting antithrombotic therapy. Data from VTE prophylaxis trials and bridging studies consistently show that bleeding complications occur more frequently when anticoagulation is started too early, and antithrombotic therapy should generally be delayed 24 hours in patients at average risk and 48 to 72 hours in patients at high risk or consequence for postoperative bleeding.[8, 60, 65]

Aspirin increases the risk of surgical blood loss and transfusion by up to 20%, and by up to 50% when given in combination with clopidogrel, but with the exception of intracranial surgery, there does not appear to be an increase in perioperative morbidity or mortality with either of these agents.[66]

Mitigating the Risk of Thromboembolism

Once the decision has been made to temporarily discontinue warfarin, the next consideration is whether to bridge with a short acting anticoagulant (typically subcutaneous LMWH or intravenous UFH) during the period of time when the INR is subtherapeutic. Conceptually, one would expect this strategy would minimize the risk of thromboembolism, but its efficacy has never been clearly demonstrated. In fact, in a systematic review and meta‐analysis of 34 studies that compared the rates of thromboembolism among bridged and nonbridged patients, heparin therapy did not reduce the risk of thromboembolic events (odds ratio: 0.80; 95% confidence interval: 0.421.54), but did result in higher rates of periprocedural bleeding.[60]

The applicability of these results to clinical practice are limited by the heterogeneity of the data used in the analysis; specifically, bridging strategies varied (including therapeutic, intermediate, and prophylactic dose regimens), there was wide variation in the types of surgery (and therefore bleeding risk), and because the majority of studies were observational, there is a significant likelihood of confounding by indication (ie, patients at high risk for thromboembolism are more likely to receive bridging therapy), and thus the benefit of this strategy may be underestimated. It is also important to note that in the majority studies anticoagulation was restarted <24 hours after the procedure, which likely contributed to the increased rate of bleeding.

Therefore, although bridging therapy is not indicated for patients at low risk, it is premature to conclude that it should be avoided in patients at moderate or high risk for thromboembolism. The results of 2 ongoing, randomized, placebo‐controlled trials of bridging therapy in patients taking warfarin for atrial fibrillation (Effectiveness of Bridging Anticoagulation for Surgery [BRIDGE]) or mechanical heart values (A Double Blind Randomized Control Trial of Post‐Operative Low Molecular Weight Heparin Bridging Therapy Versus Placebo Bridging Therapy for Patients Who Are at High Risk for Arterial Thromboembolism [PERIOP‐2]) should help to answer this question.[67, 68]

The uncertainty regarding the benefits of bridging therapy is reflected in the changes to the most recent ACCP guidelines. In 2008, the ACCP recommended low‐dose LMWH or no bridging for patients at low risk (grade 2C), therapeutic‐dose bridging for patients at moderate risk (grade 2C), and therapeutic‐dose bridging for patients at high risk for thromboembolism (Grade 1C).[56] In 2012, the ACCP recommended against bridging for low‐risk patients (grade 2C), made no specific recommendation regarding moderate‐risk patients, and offered a less robust recommendation for bridging in high‐risk patients (grade 2C).[8]

Until the results of the BRIDGE and PERIOP‐2 trials are available, the author still favors therapeutic bridging for patients at high risk and selected patients at moderate risk for thromboembolism, provided sufficient time is allowed for postoperative hemostasis before anticoagulation is restarted. For procedures with a high risk or consequence of bleeding, intravenous UFH (without a bolus) is a reasonable initial postoperative strategy to insure that anticoagulation is tolerated before committing to LMWH. Indirect evidence supports the use of prophylactic or intermediate‐dose bridging regimens in patients for whom the primary consideration is the prevention of recurrent VTE, but data to show that this strategy is effective for the prevention of arterial thromboembolism are lacking.

Intravenous glycoprotein IIb/IIIa inhibitors are sometimes used to bridge high‐risk patients with coronary artery stents who must stop antiplatelet therapy prior to a procedure, but the data to support this practice are limited and observational in nature.[69, 70]

STARTING AND STOPPING ANTITHROMBOTIC THERAPY

Warfarin

For patients on warfarin, the INR at which it is safe to perform invasive procedures is unknown. Normal hemostasis requires clotting factor levels of approximately 20% to 40% of normal,[71] which generally corresponds to an INR of <1.5, whereas for most indications, therapeutic anticoagulation is achieved when the INR is between 2.0 and 3.5. However, because the relationship between the INR and the levels of clotting factors is nonlinear, for a given patient, the INR may be abnormal (ie, >1) despite levels of clotting factors that are sufficient for periprocedural hemostasis.[72, 73, 74, 75] Because of its relatively long half‐life (3642 hours), warfarin should be stopped 6 days (skip 5 doses) prior to a procedure to achieve an INR of <1.5, but can safely be restarted the same day in most patients.

Heparins

The half‐life of intravenous heparin is dose dependent, and at therapeutic levels is approximately 60 minutes; therefore, it should be discontinued 4 to 6 hours (5 half‐lives) before performing an invasive procedure.[76] The half‐life of subcutaneous LMWHs ranges from 3 to 7 hours in healthy volunteers,[23, 24, 25] and is often longer in patients for whom these medications are commonly prescribed.[77, 78] Therefore, when administered at therapeutic doses twice daily, the last dose should be given in the morning the day before the procedure, and for therapeutic once‐daily regimens, the last dose should be reduced by 50%.[8] The optimal time to discontinue prophylactic doses of LWMH prior to an invasive procedure is unclear, but a minimum of 12 hours is recommended.[22, 79] Because LWMHs are renally cleared, longer intervals are needed for patients with impaired renal function.[76, 80]

New Oral Anticoagulants

The manufacturer of rivaroxaban recommends that if anticoagulation must be discontinued, it be stopped at least 24 hours before the procedure.[81] Although this may be sufficient for procedures with a low risk or consequence of bleeding, the half‐life of rivaroxaban is between 8 and 10 hours, and therefore 48 hours (45 half‐lives) is required to ensure minimal residual anticoagulant effect.

Apixaban has a clearance half‐life of 6 hours, but displays prolonged absorption such that its effective half‐life is 12 hours after repeated dosing. The manufacturer recommends that it be stopped at least 24 hours prior to a procedure with a low risk or consequence of bleeding, and 48 hours prior to a procedure with a high risk or consequence of bleeding.[82]

The manufacturer of dabigatran recommends that the drug be discontinued 1 to 2 days (creatinine clearance (CrCl) 50 mL/min) or 3 to 5 days (CrCl <50 mL/min) before invasive or surgical procedures, and that longer times be considered when complete hemostasis is required.[83] Given that the half‐life of dabigatran is 14 to 17 hours, the author recommends that it be stopped at least 2 days (3 half‐lives) prior to a procedure with a low risk or consequence of bleeding, and 3 days (45 half‐lives) prior to a procedure with a high risk or consequence of bleeding.

The clearance of all the NOACs is significantly prolonged in patients with renal impairment, and a longer interval between the last dose and the procedure is necessary in patients with renal failure to ensure normal hemostasis (Table 3).

The effect of the NOACs on the standard clotting assays are complex and vary depending on drug dose, the type of reagents used, and the calibration of the equipment. For dabigatran, the activated partial thromboplastin time (aPTT) and the thrombin time (TT) are sufficiently sensitive to allow for a qualitative assessment of drug effect, such that a normal aPTT indicates the absence, or a very low level of an anticoagulant effect, and a normal TT essentially rules out an effect. Accurate quantitative testing of dabigatran requires an appropriately calibrated dilute thrombin test or ecarin clotting time assay.[84, 85]

Depending on the thromboplastin reagent used, the prothrombin time (PT) may be sufficiently sensitive to rivaroxaban that a normal level rules out a residual drug effect,[86] but this does not hold true for apixaban, which has minimal effect on the PT at therapeutic concentrations. The aPTT is insensitive to both rivaroxaban and apixaban and cannot be used for assessing residual drug effect. Accurate quantitative testing of rivaroxaban or apixaban requires an anti‐factor Xa assay calibrated for use with these agents.[84]

Antiplatelet Agents

Aspirin irreversibly inhibits platelet cyclooxygenase activity, and the thienopyridines clopidogrel and prasugrel, irreversibly inhibit the platelet P2Y12 receptor. As such, the biological effects of these medications persist until the platelet pool has turned over, a process that occurs at 10% to 12% per day and takes 7 to 10 days to complete.[87] The minimum number of functional platelets required to ensure adequate periprocedural hemostasis is unknown, but is likely between 50 and 100,000/L.[88] Therefore, assuming a platelet pool of 200,000/L, most patients will regenerate an adequate number of functional platelets by 5 days after discontinuing therapy, and nearly all will have normal platelet function by 10 days. Determining the risk of bleeding prior to complete turnover of the platelet pool is further complicated by genetic variability between patients in drug metabolism and the degree of platelet inhibition by these agents.[89]

Owing to this complexity, guidelines and prescribing recommendations are inconsistent. The ACCP recommends stopping antiplatelet agents 7 to 10 days prior to an invasive procedure, and the ACC/AHA makes no specific recommendations at all.[90] Based on data from patients undergoing cardiac bypass surgery, it is recommended that clopidogrel be stopped 5 days, and prasugrel 7 days, prior to an invasive procedure.[91, 92] The elimination half‐life of ticlodipine is sufficiently long (up to 96 hours after repeated dosing) that it should be stopped 10 to 14 days prior to an invasive procedure.[87] Ticagrelor is a reversible P2Y12 receptor inhibitor with a half‐life of approximately 8 hours and should therefore have minimal effect by 3 days after discontinuation; however, the manufacturer recommends that it be stopped 5 days prior to an invasive procedure.[93]

The optimal time to restart antiplatelet agents after an invasive procedure is also unknown. The 2008 ACCP guidelines recommended restarting aspirin and/or clopidogrel in 24 hours, or as hemostasis allows,[56] whereas neither the 2007 or 2009 ACC/AHA guidelines,[90] or the most recent 2012 ACCP guidelines,[8] offer specific recommendations. Aspirin, prasugrel, and ticagrelor have a rapid onset of action, whereas the full antiplatelet effect of clopidogrel does not occur for several days, and for patients in whom more rapid platelet inhibition is desired, a loading dose (300600 mg) may be appropriate.[87]

CONCLUSIONS

Deciding on an optimal periprocedural antithrombotic management strategy is a common challenge for hospitalists that requires careful consideration of both patient and procedure related‐risk factors for bleeding and thrombosis, as well as the consequences of delaying or forgoing the procedure altogether. For many procedures, there is evidence that antithrombotic therapy can be safely continued, thereby obviating the risk associated with interrupting therapy. When antithrombotic therapy must be stopped, it should be done in a manner that appropriately balances the risks and consequence of periprocedural bleeding and thromboembolism. Strategies to decrease the risk of perioperative bleeding include allowing sufficient time for the effects of antithrombotic therapy to subside before starting the procedure, and ensuring adequate time for hemostasis before restarting antithrombotic therapy. Bridging therapy may provide net clinical benefit for patients at moderate to high risk for thromboembolism, but this will not be clear until the results of several ongoing bridging trials are available. The periprocedural antithrombotic management strategy should be developed in collaboration with the relevant providers and with active participation by the patient in all decisions and treatment plans. Standardized protocols and documentation can help to minimize unintended variation in practice and improve information transfer during transitions of care.

Acknowledgements

The author would like to thank Shoshana and Lola Herzig for their support in the design and preparation of the manuscript.

Disclosure: Nothing to report.

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References
  1. Dressler DD, Pistoria MJ, Budnitz TL, McKean SC, Amin AN. Core competencies in hospital medicine: development and methodology. J Hosp Med. 2006;1(suppl 1):4856.
  2. Thakkar R, Wright SM, Alguire P, Wigton RS, Boonyasai RT. Procedures performed by hospitalist and non‐hospitalist general internists. J Gen Int Med. 2010;25(5):448452.
  3. Horlocker TT, Wedel DJ, Rowlingson JC, et al. Regional anesthesia in the patient receiving antithrombotic or thrombolytic therapy: American Society of Regional Anesthesia and Pain Medicine evidence‐based guidelines (Third Edition). Reg Anesth Pain Med. 2010;35(1):64101.
  4. ASGE Standards of Practice Committee, Anderson MA, Ben‐Menachem T, Gan SI, et al. Management of antithrombotic agents for endoscopic procedures. Gastrointest Endosc. 2009;70(6):10601070.
  5. Patel IJ, Davidson JC, Nikolic B, et al. Consensus guidelines for periprocedural management of coagulation status and hemostasis risk in percutaneous image‐guided interventions. J Vasc Interv Radiol. 2012;23(6):727736.
  6. Bonow RO, Carabello BA, Chatterjee K, et al. 2008 Focused update incorporated into the ACC/AHA 2006 guidelines for the management of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 1998 Guidelines for the Management of Patients With Valvular Heart Disease): endorsed by the Society of Cardiovascular Anesthesiologists, Society for Cardiovascular Angiography and Interventions, and Society of Thoracic Surgeons. Circulation. 2008;118(15):e523e661.
  7. Grines CL, Bonow RO, Casey DE, et al. Prevention of premature discontinuation of dual antiplatelet therapy in patients with coronary artery stents: a science advisory from the American Heart Association, American College of Cardiology, Society for Cardiovascular Angiography and Interventions, American College of Surgeons, and American Dental Association, with representation from the American College of Physicians. J Am Coll Cardiol. 2007;49(6):734739.
  8. Douketis JD, Spyropoulos AC, Spencer FA, et al. Perioperative management of antithrombotic therapy: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 Suppl):e326Se350S.
  9. Schulman S, AngerAS U, Bergqvist D, et al. Definition of major bleeding in clinical investigations of antihemostatic medicinal products in surgical patients. J Thromb Haemost. 2010;8(1):202204.
  10. Spyropoulos AC, Turpie AG, Dunn AS, et al. Clinical outcomes with unfractionated heparin or low‐molecular‐weight heparin as bridging therapy in patients on long‐term oral anticoagulants: the REGIMEN registry. J Thromb Haemost. 2006;4(6):12461252.
  11. Manchikanti L, Falco FJ, Benyamin RM, et al. Assessment of bleeding risk of interventional techniques: a best evidence synthesis of practice patterns and perioperative management of anticoagulant and antithrombotic therapy. Pain Physician. 2013;16(2 suppl):Se261Se318.
  12. Dunn AS, Turpie AG. Perioperative management of patients receiving oral anticoagulants: a systematic review. Arch Intern Med. 2003;163(8):901908.
  13. Salvati G, Punzi L, Pianon M, et al. Frequency of the bleeding risk in patients receiving warfarin submitted to arthrocentesis of the knee [in Italian]. Reumatismo. 2003;55(3):159163.
  14. Thumboo J, O'Duffy JD. A prospective study of the safety of joint and soft tissue aspirations and injections in patients taking warfarin sodium. Arthritis Rheum. 1998;41(4):736739.
  15. Ahmed I, Gertner E. Safety of arthrocentesis and joint injection in patients receiving anticoagulation at therapeutic levels. Am J Med. 2012;125(3):265269.
  16. Moen V, Dahlgren N, Irestedt L. Severe neurological complications after central neuraxial blockades in Sweden 1990–1999. Anesthesiology. 2004;101(4):950959.
  17. Green L, Machin SJ. Managing anticoagulated patients during neuraxial anaesthesia. Br J Haematol. 2010;149(2):195208.
  18. Stafford‐Smith M. Impaired haemostasis and regional anaesthesia. Can J Anaesth. 1996;43(5 pt 2):R129R141.
  19. Sinclair AJ, Carroll C, Davies B. Cauda equina syndrome following a lumbar puncture. J Clin Neurosci. 2009;16(5):714716.
  20. United States Food and Drug Safety Communication: updated recommendations to decrease risk of spinal column bleeding and paralysis in patients on low molecular weight heparins. Available at: http://www.fda.gov/Drugs/DrugSafety/ucm373595.htm. Accessed January 6, 2014.
  21. Davis JJ, Bankhead BR, Eckman EJ, Wallace A, Strunk J. Three‐times‐daily subcutaneous unfractionated heparin and neuraxial anesthesia: a retrospective review of 928 cases. Reg Anesth Pain Med. 2012;37(6):623626.
  22. Gogarten W, Vandermeulen E, Aken H, et al. Regional anaesthesia and antithrombotic agents: recommendations of the European Society of Anaesthesiology. Eur J Anaesthesiol. 2010;27(12):9991015.
  23. Eisai Inc. Fragmin (dalteparin sodium injection) full prescribing information. 2009. Available at: http://us.eisai.com/wps/wcm/connect/Eisai/Home/Our+Products/FRAGMIN. Accessed January 6, 2014
  24. Sanofi‐Aventis. Lovenox (enoxaparin sodium injection) full prescribing information. 2013. Available at: http://products.sanofi.us/lovenox/lovenox.html. Accessed January 6, 2014.
  25. LEO Pharmaceutical Products. Innohep (tinzaparin sodium injection) full prescribing information. 2008. Available at: http://www.accessdata.fda.gov/drugsatfda_docs/label/2008/020484s011lbl.pdf. Accessed January 6, 2014.
  26. Horlocker TT, Wedel DJ, Schroeder DR, et al. Preoperative antiplatelet therapy does not increase the risk of spinal hematoma associated with regional anesthesia. Anesth Analg. 1995;80(2):303309.
  27. Patel IJ, Davidson JC, Nikolic B, et al. Addendum of newer anticoagulants to the SIR consensus guideline. J Vasc Interv Radiol. 2013;24(5):641645.
  28. Pache I, Bilodeau M. Severe haemorrhage following abdominal paracentesis for ascites in patients with liver disease. Aliment Pharmacol Ther. 2005;21(5):525529.
  29. Mercaldi CJ, Lanes SF. Ultrasound guidance decreases complications and improves the cost of care among patients undergoing thoracentesis and paracentesis. Chest. 2013;143(2):532538.
  30. Runyon BA. Management of adult patients with ascites due to cirrhosis. Hepatology. 2004;39(3):841856.
  31. Tripodi A, Mannucci PM. The coagulopathy of chronic liver disease. N Engl J Med. 2011;365(2):147156.
  32. Doyle JJ, Hnatiuk OW, Torrington KG, Slade AR, Howard RS. Necessity of routine chest roentgenography after thoracentesis. Ann Intern Med. 1996;124(9):816820.
  33. Wrightson JM, Helm EJ, Rahman NM, Gleeson FV, Davies RJ. Pleural procedures and pleuroscopy. Respirology. 2009;14(6):796807.
  34. Patel PA, Ernst FR, Gunnarsson CL. Ultrasonography guidance reduces complications and costs associated with thoracentesis procedures. J Clin Ultrasound. 2012;40(3):135141.
  35. Duncan DR, Morgenthaler TI, Ryu JH, Daniels CE. Reducing iatrogenic risk in thoracentesis: establishing best practice via experiential training in a zero‐risk environment. Chest. 2009;135(5):13151320.
  36. Daniels CE, Ryu JH. Improving the safety of thoracentesis. Curr Opin Pulm Med. 2011;17(4):232236.
  37. Puchalski JT, Argento AC, Murphy TE, Araujo KL, Pisani MA. The safety of thoracentesis in patients with uncorrected bleeding risk. Ann Am Thorac Soc. 2013;10(4):336341.
  38. Hibbert RM, Atwell TD, Lekah A, et al. Safety of ultrasound‐guided thoracentesis in patients with abnormal preprocedural coagulation parameters. Chest. 2013;144(2):456463.
  39. Patel MD, Joshi SD. Abnormal preprocedural international normalized ratio and platelet counts are not associated with increased bleeding complications after ultrasound‐guided thoracentesis. AJR Am J Roentgenol. 2011;197(1):W164W168.
  40. McVay PA, Toy PT. Lack of increased bleeding after paracentesis and thoracentesis in patients with mild coagulation abnormalities. Transfusion. 1991;31(2):164171.
  41. Dammert P, Pratter M, Boujaoude Z. Safety of ultrasound‐guided small‐bore chest tube insertion in patients on clopidogrel. J Bronchology Interv Pulmonol. 2013;20(1):1620.
  42. Zalt MB, Bechara RI, Parks C, Berkowitz DM. Effect of routine clopidogrel use on bleeding complications after ultrasound‐guided thoracentesis. J Bronchology Interv Pulmonol. 2012;19(4):284287.
  43. McGee DC, Gould MK. Preventing complications of central venous catheterization. N Engl J Med. 2003;348(12):11231133.
  44. Ruesch S, Walder B, Tramer MR. Complications of central venous catheters: internal jugular versus subclavian access—a systematic review. Crit Care Med. 2002;30(2):454460.
  45. Theodoro D, Krauss M, Kollef M, Evanoff B. Risk factors for acute adverse events during ultrasound‐guided central venous cannulation in the emergency department. Acad Emerg Med. 2010;17(10):10551061.
  46. Kusminsky RE. Complications of central venous catheterization. J Am Coll Surg. 2007;204(4):681696.
  47. Wu SY, Ling Q, Cao LH, Wang J, Xu MX, Zeng WA. Real‐time two‐dimensional ultrasound guidance for central venous cannulation: a meta‐analysis. Anesthesiology. 2013;118(2):361375.
  48. Doerfler ME, Kaufman B, Goldenberg AS. Central venous catheter placement in patients with disorders of hemostasis. Chest. 1996;110(1):185188.
  49. DeLoughery TG, Liebler JM, Simonds V, Goodnight SH. Invasive line placement in critically ill patients: do hemostatic defects matter? Transfusion. 1996;36(9):827831.
  50. Kander T, Frigyesi A, Kjeldsen‐Kragh J, Karlsson H, Rolander F, Schott U. Bleeding complications after central line insertions: relevance of pre‐procedure coagulation tests and institutional transfusion policy. Acta Anaesthesiol Scand. 2013;57(5):573579.
  51. Weigand K, Encke J, Meyer FJ, et al. Low levels of prothrombin time (INR) and platelets do not increase the risk of significant bleeding when placing central venous catheters. Med Klin (Munich). 2009;104(5):331335.
  52. Della Vigna P, Monfardini L, Bonomo G, et al. Coagulation disorders in patients with cancer: nontunneled central venous catheter placement with US guidance—a single‐institution retrospective analysis. Radiology. 2009;253(1):249252.
  53. Tercan F, Ozkan U, Oguzkurt L. US‐guided placement of central vein catheters in patients with disorders of hemostasis. Eur J Radiol. 2008;65(2):253256.
  54. Carino GP, Tsapenko AV, Sweeney JD. Central line placement in patients with and without prophylactic plasma. J Crit Care. 2012;27(5):529.e529e513.
  55. Siegal DM, Garcia DA, Crowther MA. How I treat: target specific oral anticoagulant associated bleeding [published online ahead of print January 2, 2014]. Blood. doi: 10.1182/blood‐2013‐09‐529784.
  56. Douketis JD, Berger PB, Dunn AS, et al. The perioperative management of antithrombotic therapy: American College of Chest Physicians evidence‐based clinical practice guidelines (8th edition). Chest. 2008;133(6 suppl):299S339S.
  57. Kearon C, Hirsh J. Management of anticoagulation before and after elective surgery. N Engl J Med. 1997;336(21):15061511.
  58. Garcia DA, Regan S, Henault LE, et al. RIsk of thromboembolism with short‐term interruption of warfarin therapy. Arch Intern Med. 2008;168(1):6369.
  59. Healey JS, Eikelboom J, Douketis J, et al. Periprocedural bleeding and thromboembolic events with dabigatran compared with warfarin: results from the Randomized Evaluation of Long‐Term Anticoagulation Therapy (RE‐LY) randomized trial. Circulation. 2012;126(3):343348.
  60. Siegal D, Yudin J, Kaatz S, Douketis JD, Lim W, Spyropoulos AC. Periprocedural heparin bridging in patients receiving vitamin K antagonists: systematic review and meta‐analysis of bleeding and thromboembolic rates. Circulation. 2012;126(13):16301639.
  61. Gould MK, Garcia DA, Wren SM, et al. Prevention of VTE in nonorthopedic surgical patients: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 Suppl):e227S277S.
  62. McBane RD, Wysokinski WE, Daniels PR, et al. Periprocedural anticoagulation management of patients with venous thromboembolism. Arterioscler Thromb Vasc Biol. 2010;30(3):442448.
  63. Windecker S, Meier B. Late coronary stent thrombosis. Circulation. 2007;116(17):19521965.
  64. Werkum JW, Heestermans AA, Zomer AC, et al. Predictors of coronary stent thrombosis: the Dutch Stent Thrombosis Registry. J Am Coll Cardiol. 2009;53(16):13991409.
  65. Tafur AJ, McBane R, Wysokinski WE, et al. Predictors of major bleeding in peri‐procedural anticoagulation management. J Thromb Haemost. 2012;10(2):261267.
  66. Chassot PG, Delabays A, Spahn DR. Perioperative antiplatelet therapy: the case for continuing therapy in patients at risk of myocardial infarction. Br J Anaesth. 2007;99(3):316328.
  67. Ortel TL, Hasselblad V. Effectiveness of bridging anticoagulation for surgery (the BRIDGE Study). Available at: www.ClinicalTrials.gov. Identifier: NCT00786474. Accessed October 22, 2013.
  68. Kovacs MJ. A safety and effectiveness study of LMWH bridging therapy versus placebo bridging therapy for patients on long term warfarin and require temporary interruption of their warfarin (PERIOP2). Available at: www.ClinicalTrials.gov. Identifier: NCT00432796. Accessed October 20, 2013.
  69. Alshawabkeh LI, Prasad A, Lenkovsky F, et al. Outcomes of a preoperative “bridging” strategy with glycoprotein IIb/IIIa inhibitors to prevent perioperative stent thrombosis in patients with drug‐eluting stents who undergo surgery necessitating interruption of thienopyridine administration. EuroIntervention. 2013;9(2):204211.
  70. Rassi AN, Blackstone E, Militello MA, et al. Safety of “bridging” with eptifibatide for patients with coronary stents before cardiac and non‐cardiac surgery. Am J Cardiol. 2012;110(4):485490.
  71. Edmunds LH. Hemostatic problems in surgical patients. In: Colman RW HJ, Marder VJ, Clowes AW, George JN, ed. Hemostasis and Thrombosis. 4th ed. Philadelphia, PA: Lippincott Williams 2001:1033.
  72. Dzik WS. Reversal of drug‐induced anticoagulation: old solutions and new problems. Transfusion. 2012;52:45S55S.
  73. Larson BJ, Zumberg MS, Kitchens CS. A feasibility study of continuing dose‐reduced warfarin for invasive procedures in patients with high thromboembolic risk. Chest. 2005;127(3):922927.
  74. Marietta M, Bertesi M, Simoni L, et al. A simple and safe nomogram for the management of oral anticoagulation prior to minor surgery. Clin Lab Haematol. 2003;25(2):127130.
  75. Gulati G, Hevelow M, George M, Behling E, Siegel J. International normalized ratio versus plasma levels of coagulation factors in patients on vitamin K antagonist therapy. Arch Pathol Lab Med. 2011;135(4):490494.
  76. Garcia DA, Baglin TP, Weitz JI, Samama MM. Parenteral anticoagulants: antithrombotic therapy and prevention of thrombosis, 9th ed: American College Of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e24Se43S.
  77. Douketis JD, Woods K, Foster GA, Crowther MA. Bridging anticoagulation with low‐molecular‐weight heparin after interruption of warfarin therapy is associated with a residual anticoagulant effect prior to surgery. Thromb Haemost. 2005;94(3):528531.
  78. O'Donnell MJ, Kearon C, Johnson J, et al. Brief communication: Preoperative anticoagulant activity after bridging low‐molecular‐weight heparin for temporary interruption of warfarin. Ann Intern Med. 2007;146(3):184187.
  79. Horlocker TT. Regional anaesthesia in the patient receiving antithrombotic and antiplatelet therapy. Br J Anaesth. 2011;107(suppl 1):i96i106.
  80. Lim W, Dentali F, Eikelboom JW, Crowther MA. Meta‐analysis: low‐molecular‐weight heparin and bleeding in patients with severe renal insufficiency. Ann Intern Med. 2006;144(9):673684.
  81. Janssen Pharmaceuticals, Inc. Xarelto (rivaroxaban) full prescribing information. 2013. Available at: http://www.xareltohcp.com/sites/default/files/pdf/xarelto_0.pdf#zoom=100. Accessed October 1, 2013.
  82. Bristol Meyers Squibb, Inc. Eliquis (apixaban) full prescribing information. 2013. Available at: http://packageinserts.bms.com/pi/pi_eliquis.pdf. Accessed October 1, 2013.
  83. Boehringer Ingelheim Pharmaceuticals I. Pradaxa (dabigatran etexilate mesylate) full prescribing information. Available at: http://bidocs.boehringer‐ingelheim.com/BIWebAccess/ViewServlet.ser?docBase= renetnt11(2):245252.
  84. Tripodi A. The laboratory and the direct oral anticoagulants. Blood. 2013;121(20):40324035.
  85. Douxfils J, Mullier F, Loosen C, Chatelain C, Chatelain B, Dogne JM. Assessment of the impact of rivaroxaban on coagulation assays: laboratory recommendations for the monitoring of rivaroxaban and review of the literature. Thromb Res. 2012;130(6):956966.
  86. Eikelboom JW, Hirsh J, Spencer FA, Baglin TP, Weitz JI. Antiplatelet drugs: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e89S119S.
  87. Slichter SJ. Evidence‐based platelet transfusion guidelines. Hematology Am Soc Hematol Educ Program. 2007:172178.
  88. Grove EL, Hossain R, Storey RF. Platelet function testing and prediction of procedural bleeding risk. Thromb Haemost. 2013;109(5):817824.
  89. Darvish‐Kazem S, Gandhi M, Marcucci M, Douketis JD. Perioperative management of antiplatelet therapy in patients with a coronary stent who need non‐cardiac surgery: a systematic review of clinical practice guidelines. Chest. 2013;144(6):18481856.
  90. Eli Lilly Pharmaceuticals, Inc. Effient (prasugrel) full prescribing information. 2012. Available at: http://pi.lilly.com/us/effient.pdf. Accessed October 1, 2013.
  91. Fitchett D, Mazer CD, Eikelboom J, Verma S. Antiplatelet therapy and cardiac surgery: review of recent evidence and clinical implications. Can J Cardiol. 2013;29(9):10421047.
  92. AstraZeneca. Brilinta (ticagrelor) full prescribing information. 2013. Available at: http://www1.astrazeneca‐us.com/pi/brilinta.pdf. Accessed October 1, 2013.
  93. Ferraris VA, Saha SP, Oestreich JH, et al. 2012 update to the Society of Thoracic Surgeons guideline on use of antiplatelet drugs in patients having cardiac and noncardiac operations. Ann Thorac Surg. 2012;94(5):17611781.
  94. Spyropoulos AC, Douketis JD. How I treat anticoagulated patients undergoing an elective procedure or surgery. Blood. 2012;120(15):29542962.
  95. Garcia DA, Baglin TP, Weitz JI, Samama MM, American College of Chest Physicians. Parenteral anticoagulants: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e24Se43S.
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The periprocedural management of antithrombotic medications is a common challenge for hospitalists, for which there is limited high‐quality evidence to guide clinical decision making. The introduction of third‐generation antiplatelet agents (prasugrel and ticagrelor) and the new oral anticoagulants (rivaroxaban, apixaban, and dabigatran), has added an additional layer of complexity to clinical management.

This article will provide a conceptual framework for the periprocedural management of antithrombotic therapy, with a particular focus on procedures that are considered core competencies by the Society of Hospital Medicine; these include: arthrocentesis, lumbar puncture, paracentesis, thoracentesis, and central line placement (Table 1).[1, 2] The recommendations in this article are based on a review of published guidelines and consensus statements and their supporting literature.[3, 4, 5, 6, 7, 8] Additional articles were identified by performing a PubMed keyword search using the terms perioperative management or periprocedural management and anticoagulation or antithrombotic or antiplatelet in combination with keywords relevant to the content areas (eg, arthrocentesis, lumbar puncture). Articles for inclusion were chosen based on methodological quality and relevance to hospital medicine.

There are several questions that must be addressed when developing a periprocedural antithrombotic management strategy:

  1. What is the patient's risk of bleeding if antithrombotic therapy is continued?
  2. What is the patient's risk of thromboembolism if antithrombotic therapy is interrupted?
  3. Are there interventions that can decrease the risk of periprocedural bleeding and/or thromboembolism?

WHAT IS THE PATIENT'S RISK OF BLEEDING IF ANTITHROMBOTIC THERAPY IS CONTINUED?

Although the risk of bleeding is well described for many procedures, there are limited data on how that risk is affected by coagulopathy in general and antithrombotic medications in particular. When these data are available, they are largely derived from case series or bridging registries, which include heterogeneous patient populations and nonstandardized definitions of bleeding.[8, 9, 10] As such, few procedural or surgical professional societies have published guidelines on the periprocedural management of antithrombotic therapy,[3, 4, 5, 11]and guidelines from the American College of Chest Physicians (ACCP), the American College of Cardiology (ACC), and American Heart Association (AHA) only provide specific recommendations regarding minor ambulatory procedures.[6, 7, 8]

Procedures can be categorized as low or high risk for bleeding based on the following considerations: the extent of associated tissue injury, proximity to vital organs or vascular structures, the ability to readily detect and control bleeding, and the morbidity associated with a bleeding complication (eg, a small bleed into the epidural space is potentially catastrophic, whereas a large bleed from the colon often results in no permanent harm). For procedures with a high risk or consequence of bleeding, anticoagulants must be stopped, whereas in some cases antiplatelet agents can be safely continued. For procedures with a low risk or consequence of bleeding, it may be possible to continue both anticoagulant and antiplatelet agents.

Recommended Periprocedural Management of Antithrombotic Therapy
Procedure Antithrombotic Therapy
Aspirin Thienopyridines Prophylactic UFH or LWMH Therapeutic UFH or LMWH Warfarin NOACs
  • NOTE:+= safe to continue during procedure;= unsafe to continue during procedure;= insufficient data, individualized approach recommended. Abbreviations: BID, twice daily; LMWH, low‐molecular‐weight heparin; NOACs, new oral anticoagulants (rivaroxaban, apixiban, dabigatran); UFH, unfractionated heparin.

Arthrocentesis[12, 13, 14, 15] + + + + + +
Lumbar puncture[3] + 5000 units UFH BID
Paracentesis[28, 29, 30] + + +
Thoracentesis[37, 38, 39, 40, 41, 42] + + +
Central venous catheter insertion[48, 49, 50, 51, 52, 53] + + +

Because procedures in hospitalized patients are most often performed for the purpose of diagnosing or treating an emergent condition, the risk of delaying the procedure while antithrombotic medications are held must be part of the overall risk‐benefit calculation.

Arthrocentesis

Bleeding complications from arthrocentesis are very rare, and there are few data on the additional risk associated with antithrombotic therapy.[12, 13, 14] In a retrospective cohort study, investigators determined the incidence of clinically significant bleeding (defined as bleeding requiring reversal of anticoagulation, prolonged manual pressure, surgical intervention, hospital admission, or delay in hospital discharge) and procedure‐related pain among 514 patients on antithrombotic therapy referred for arthrocentesis or injection of the hip, shoulder, or knee. Four hundred fifty‐six procedures were performed in patients without interrupting warfarin therapy, all of whom maintained an international normalized ratio (INR)2, and 184 procedures were performed in patients who had stopped their warfarin to achieve an INR <2. Antiplatelet therapy was routinely continued in both groups, with 48% of patients taking aspirin and 9% clopidogrel. There was 1 bleeding complication (0.2%) in a patient with an INR of 2.3 who was also taking aspirin, and 2 patients developed procedure‐related pain (INR 3.3 and 5.3, neither taking antiplatelet medications).[15]

Based on the available evidence, arthrocentesis appears to be safe in patients on therapeutic warfarin, with or without aspirin and/or clopidogrel. At present, there are no published studies that address the risk of arthrocentesis in patients taking other antiplatelet or anticoagulant medications, but given the low overall risk of this procedure, it is reasonable to infer that these medications can also be safely continued.

Lumbar Puncture

The incidence of bleeding complications from diagnostic lumbar puncture is unknown, but is likely similar to that seen with spinal anesthesia, where in a large retrospective observational study, spinal hematoma occurred in 1:165,000 spinal block procedures.[16] Factors associated with an increased risk of spinal hematoma include traumatic tap, advanced age, female gender, spinal cord or vertebral column abnormalities, coagulopathy, and not allowing sufficient time between stopping and restarting antithrombotic therapy.[3, 17, 18, 19, 20]

Therapeutic anticoagulation must be stopped and prophylactic anticoagulation delayed before performing a lumbar puncture. The 1 exception is low‐dose unfractionated heparin (UFH), which the American Society for Regional Anesthesia (ARSA) recommends continuing in patients undergoing neuraxial procedures, provided the total dose is 5000 U twice daily. This assessment is based on observational data, surveys of practice patterns, and decades of use without evidence of complications; in fact, there are only 5 case reports of spinal hematomas in this population.[3] However, because these data are from surgical populations, in which heparin thromboprophylaxis is typically dosed at 5000 units twice daily, there are limited data on the safety of higher or more frequent doses of heparin. In a retrospective cohort study of 928 patients who received thoracic epidural analgesia in conjunction with UFH dosed at 5000 U, 3 times daily, there were no cases of neuraxial bleeding, but given the rarity of neuraxial hematoma, it is not possible to draw any conclusions from this relatively small sample size.[21]

In November 2013, based on surveillance data showing increased risk for spinal or epidural hematoma associated with low‐molecular‐weight heparin (LMWH), the US Food and Drug Administration (FDA) issued a drug safety communication recommending that neuraxial procedures be delayed for 12 hours after prophylactic LMWH and 24 hours after therapeutic LMWH, and that LMWH not be restarted for at least 4 hours after catheter removal.[20] These recommendations are largely consistent with existing guidelines[3, 22] but are not explicitly stated in the package insert for any of the LMWHs available in the United States,[23, 24, 25] and the FDA is working with the manufacturers to add this information.

Nonsteroidal anti‐inflammatory drugs (NSAIDs), dipyridamole, and aspirin do not appear to increase the risk of spinal hematoma and are considered safe to continue.[11, 26] There are limited data on the safety of thienopyridine medications in neuraxial anesthesia, but based on case reports and increased bleeding rates seen in surgical populations, it is generally recommended that these medications be discontinued before performing a lumbar puncture.[3, 22, 27]

The optimal time to restart anticoagulation after a lumbar puncture is unknown. The ARSA recommends a minimum of 1 hour for UFH and 2 hours for LMWH after neuraxial catheter removal, and provides no specific guidance about other anticoagulants,[3] whereas the European Society of Anesthesiology recommends a minimum of 1 hour for UFH, 4 hours for LMWH, 4 to 6 hours for rivaroxaban and apixiban, and 6 hours for dabigatran and fondaparinux.[22] Longer time periods should be considered after a traumatic tap, and postprocedure monitoring of neurological function is recommended for all patients.

The available evidence suggests that lumbar puncture can be safely performed in patients being treated with aspirin, NSAIDs, and UFH dosed at 5000 U twice daily; the safety of higher or more frequent doses of UFH is not known. Lumbar puncture should be delayed 12 hours after prophylactic LMWH and 24 hours after therapeutic LMWH, and LMWH should not be restarted for at least 4 hours after the procedure.[20] There are limited data on the safety of thienopyridines, but they should generally be discontinued, and all other prophylactic or therapeutic anticoagulation must be stopped prior to the procedure.

Paracentesis

Bleeding complications from paracentesis are uncommon, with abdominal wall hematoma and hemoperitoneum complicating 1% and 0.01% of procedures, respectively.[28, 29, 30] Whether antithrombotic therapy increases the risk of bleeding during paracentesis is unknown, primarily because most patients for whom the procedure is indicated have coagulopathy and thrombocytopenia from liver disease, and are therefore rarely treated with these medications.

Although patients with liver disease often have an elevated INR due to impaired hepatic synthesis of clotting factors, it is incorrect to generalize the observed rate of bleeding in this population to patients with an elevated INR from warfarin therapy who may require paracentesis for reasons unrelated to liver disease (eg, malignancy or infection). The coagulopathy of liver disease reflects deficiencies in the hepatic production of both pro‐ and anticoagulant proteins, and these patients develop both thrombotic and hemorrhagic complications irrespective of their in vitro coagulation indices.[31]

Although the available evidence suggests that paracentesis can be safely performed in patients with coagulopathy from liver disease, regardless of the INR,[30] little is known about the bleeding risk in other patients, with or without antithrombotic therapy. Based on indirect evidence, it is reasonable to assume that prophylactic UFH or LWMH or antiplatelet therapy would confer minimal additional risk, whereas the safety of continuing therapeutic anticoagulation is unknown.

Thoracentesis

Bleeding complications from thoracentesis are uncommon, generally occurring in <1% of procedures.[32, 33, 34] Factors associated with increased risk of overall complications include operator inexperience, large volume drainage, and lack of ultrasound guidance.[34, 35, 36] There are no studies that specifically address the risk of bleeding in patients on anticoagulant therapy, but such patients are included in studies on the risk of bleeding with coagulopathy.[37, 38, 39, 40]

In a retrospective cohort study of 1076 ultrasound‐guided thoracenteses performed by radiologists on patients with coagulopathy (defined as thrombocytopenia or an elevated INR from any cause), there were no bleeding complications (defined as anything other than minimal symptoms not requiring intervention). Among the patients in this study, 497 (46%) patients had a preprocedure INR >1.5; 198 (24%) had an INR between 2 and 3, and 32 (4%) had an INR >3.[39]

A similar study, which compared outcomes in patients with corrected and uncorrected coagulopathy, included 744 patients with an INR >1.6 (from any cause), of which 167 received preprocedural fresh‐frozen plasma (FFP) and 577 did not. There was 1 (0.1%) bleeding complication in a patient who received prophylactic FFP and none in the group that was not transfused.[38]

In a prospective cohort of 312 patients at increased risk for bleeding (from coagulopathy or antithrombotic medications) who underwent ultrasound‐guided thoracentesis by a pulmonologist or physician's assistant, 44 (34%) had an INR >1.5 (secondary to liver disease or warfarin therapy), 15 (12%) were taking clopidogrel, and 14 (11%) were treated with therapeutic LMWH within 12 hours or therapeutic UFH within 4.5 hours of the procedure. There were no bleeding complications in any of the patients (defined as mean change in hematocrit, chest x‐ray abnormalities, hemothorax, or requirement for transfusion).[37]

Although there are no studies that specifically address the use of aspirin and bleeding complications in thoracentesis, it is generally considered safe to continue this medication,[5] and there are small studies that show that thoracentesis and small‐bore chest tubes can be safely placed in patients taking clopidogrel.[41, 42]

Thoracentesis is associated with a low rate of bleeding complications, and when performed by an experienced operator using ultrasound, warfarin does not appear to increase this risk. However, given the low overall complication rate, it is not known whether patients on warfarin would have worse outcomes in the event of more serious complications (eg, intercostal artery laceration). At present, there are no published studies that address the risk of thoracentesis in patients taking new oral anticoagulants (NOACs).

Central Venous Catheter Insertion

The incidence of bleeding complications from central venous catheter (CVC) placement varies depending on the site of insertion and definition of bleeding, with hematoma and hemothorax occurring in 0.1% to 6.9%, and 0.4% to 1.3% of procedures, respectively.[43, 44, 45] Factors that increase the likelihood of complications include operator inexperience, multiple needle passes, and lack of ultrasound guidance.[46, 47] There are no studies that specifically address the risk of bleeding from CVC placement in patients on anticoagulant therapy, but such patients are included in studies of CVC placement in patients with coagulopathy, which report similar complication rates as seen in patients with normal hemostasis.[48, 49, 50, 51, 52, 53]

In a retrospective cohort study, investigators collected information on CVC‐associated bleeding complications in 281 medical and surgical intensive care patients with coagulopathy (INR 1.5 from any cause) after they adopted a more conservative approach to plasma transfusion in their intensive care unit; specifically, the routine use of prophylactic FFP to correct coagulopathy was discouraged for patients with an INR <3 (vs usual practice using an INR cutoff of 1.5), but the final decision was left to the discretion of the attending performing or supervising the procedure. Bleeding was defined as insertion‐site hematoma, interventions other than local manual pressure, and the need for blood transfusion. One case of bleeding (hematoma) was observed in a patient with an INR of 3.9, who received FFP before the procedure. There were no complications among those with uncorrected coagulopathy, including 66 patients with an INR between 1.5 and 2.9, and 6 with an INR 3.0. Ultrasound guidance was used in 50% of CVCs placed in the internal jugular vein.[54]

Although there are no studies that specifically address the use of antiplatelet drugs and bleeding complications in CVC placement, aspirin is generally considered safe to continue,[5] and by inference, thienopyridines are expected to add minimal additional risk.

CVC placement is associated with a variable rate of bleeding complications, with hematoma being relatively common. Based on the available literature, warfarin does not appear to increase this risk, but there are limited data from which to draw firm conclusions. A femoral or jugular approach may be preferable because they allow for ultrasound visualization and are amenable to manual compression. There are no published studies that address the risk of CVC placement in patients taking NOACs, and although the risk of bleeding is probably similar to patients receiving warfarin, the lack of effective reversal agents for these medications should be part of any risk‐benefit calculation.[55]

WHAT IS THE PATIENT'S RISK OF THROMBOEMBOLISM IF ANTITHROMBOTIC THERAPY IS INTERRUPTED?

Anticoagulants

If it is determined that a procedure cannot safely be performed while continuing antithrombotic therapy, one must then consider the patient's risk of thromboembolism if these therapies are temporarily interrupted. Unfortunately, there are few robust clinical studies from which to make this assessment, and therefore most clinicians rely on the risk stratification model proposed by the ACCP, which divides patients into 3 tiers (low, moderate, high), based on their indication for anticoagulation and risk factors for thromboembolism (Table 2)[8]. The ACCP model is largely based on indirect evidence from antithrombotic therapy trials in nonoperative patients, and its application to perioperative patients necessitates several assumptions that may not hold true in practice.

American College of Chest Physicians Stratification for Perioperative Thromboembolism
Indication for Anticoagulant Therapy
Risk Stratum Mechanical Heart Valve Atrial Fibrillation VTE
  • NOTE: Abbreviations: CHADS2=congestive heart failure, hypertension, age 75 years, diabetes mellitus, and stroke or transient ischemic attack; TIA, transient ischemic attack; VKA, vitamin K antagonist; VTE, venous thromboembolism.

  • High‐risk patients may also include those with a prior stroke or TIA occurring >3 months before the planned surgery and a CHADS2 score <5, those with prior thromboembolism during temporary interruption of VKAs, or those undergoing certain types of surgery associated with an increased risk for stroke or other thromboembolism (eg, cardiac valve replacement, carotid endarterectomy, major vascular surgery).

High Thrombotic Risk
  • Any mitral valve prosthesis
  • Any caged‐ball or tilting disc aortic valve prosthesis
  • Recent (within 6 months) stroke or TIA
  • CHADS2 score of 5 or 6
  • Recent (within 3 months) stroke or TIA
  • Rheumatic valvular heart disease
  • Recent (within 3 months) VTE
  • Severe thrombophilia (eg, deficiency of protein C, protein S, or antithrombin; antiphospholipid antibodies; multiple abnormalities)
Moderate Thrombotic Risk
  • Bileaflet aortic valve prosthesis with one or more of the following risk factors: atrial fibrillation, prior stroke or TIA, hypertension, diabetes, congestive heart failure, age 75 years
  • CHADS2 score of 3 or 4
  • VTE within the past 3 to 12 months
  • Nonsevere thrombophilia (eg, heterozygous factor V Leiden or prothrombin gene mutation)
  • Recurrent VTE
  • Active cancer (treated within six months or palliative)
Low Thrombotic Risk
  • Bileaflet aortic valve prosthesis without atrial fibrillation and no other risk factors for stroke
  • CHADS2 score of 0 to 2 (assuming no prior stroke or TIA)
  • VTE >12 months previous and no other risk factors

First, it assumes that the annualized risk of a thrombotic event in nonoperative patients can be prorated to determine the short‐term risk of discontinuing antithrombotic therapy in the perioperative period. For example, it has been estimated that the risk for perioperative stroke in a patient with atrial fibrillation who temporarily interrupts anticoagulation for 1 week would be 0.1% (5% per year 52 weeks),[56, 57]and yet we know from observational data that the actual risk of perioperative stroke in similar patients is 5 to 7 times higher.[58, 59] Second, it assumes that bridging therapy will decrease the risk of thromboembolism in high‐risk patients when warfarin therapy is interrupted, a premise that is logical but has not been subject to randomized controlled trials.[60] Third, it does not take into account the surgery‐specific risk for thromboembolism, which varies significantly, with arterial thromboembolism being more common in cardiac valve, vascular, and neurologic procedures, and venous thromboembolism (VTE) being more likely in orthopedic, trauma, and cancer surgery.[61, 62] These limitations notwithstanding, the ACCP model still offers the best available framework for thrombotic risk assessment and a reasonable starting point for clinical decision making.

Antiplatelet Agents

Patients with coronary artery stents who undergo noncardiac surgery are at increased risk for adverse cardiovascular events, including acute stent thrombosis, which carries a risk of myocardial infarction and death of 70% and 30%, respectively.[63] This risk is highest during the period between stent implantation and endothelialization, a process that takes 4 to 6 weeks for bare‐metal stents (BMS) and 6 to 12 months for drug‐eluting stents (DES). Premature discontinuation of dual antiplatelet therapy is the most important risk factor for stent thrombosis during this time.[64] Although the optimal perioperative strategy for these patients is unknown, there is general agreement that elective surgery should be delayed for at least 4 weeks in patients with a BMS and 12 months for patients with a DES. If a procedure or surgery is required during this time period, every effort should be made to continue dual antiplatelet therapy; if this is not possible, aspirin should be continued, and thienopyridine therapy should be interrupted as briefly as possible (Table 3).

Recommended Timing for Periprocedural Interruption and Initiation of Antithrombotic Therapy
Recommended Interval Between Last Dose of Medication and Procedure Recommended Interval Between Procedure and First Dose of Medication, h
Low Risk or Consequence of Postprocedure Bleeding High Risk or Consequence of Postprocedure Bleeding
  • NOTE: Abbreviations: CrCl, creatinine clearance; LMWH, low‐molecular‐weight heparin; UFH, unfractionated heparin.

  • Assuming minimal platelet effect by 7 days and no effect by 10 days for (irreversible) agents: aspirin, ticlodipine, clopidogrel, and prasugrel. Ticlodipine drug clearance is prolonged by an additional 4 days after repeated dosing.

  • Ticagrelor and cilostazol half‐life depends on rate of drug clearance.

  • Five days is sufficient for cardiac surgery.[94]

  • Seven days per manufacturer[91]; drug effect may persist up to 10 days.

  • Five days per manufacturer[93]; a shorter interval is expected based on half‐life.

  • Intervals based on 45 drug half‐lives to achieve minimal residual anticoagulant effect; shorter intervals may be appropriate for procedures with low risk or consequence of bleeding. Adapted from Spyropoulos and Douketis.[95]

  • More than 90% of patients will achieve an international normalized ratio <1.5 after skipping 5 doses.[8]

  • Longer intervals are recommended for patients with CrCl <30 mL/min.[96]

  • Longer intervals are recommended for patients with CrCl <50 mL/min.[96]

  • Patients receiving dabigatran 75 mg twice daily.

  • Patients receiving rivaroxaban 15 mg daily.

Antiplatelet Medicationsa
Aspirin (81325 mg dailydipyridamole) 710 days (skip 69 doses) 24 48
Ticlodipine (250 mg twice daily) 1014 days (skip 1926 doses) 24 48
Clopidogrel (75 mg once daily) 710 days (skip 69 doses)b 24 48
Prasugrel (10 mg once daily) 710 days (skip 69 dose)c 24 48
Ticagrelor (90 mg twice daily; t =8 hours) 5 days (skip 8 doses) 24 48
Cilostazol (100 mg twice daily; t =11 hours) 3 days (skip 4 doses) 24 48
Anticoagulant Medicationse
Warfarin (t =3642 hours, but highly variable) 6 days (skip 5 doses)f 12 24
Intravenous UFH (t 60 minutes) 46 hours 24 4872
LMWH (t =37 hours)
Prophylactic dosing 12 hours# 12 2436
Therapeutic dosing
Once daily 24 hours (give 50% of last total dose)# 24 4872
Twice daily 24 hours (skip 1 dose)# 24 4872
Fondaparinux (t =17 hours, any dose) 34 days (skip 23 doses)h 24 4872
Dabigatran (150 mg twice daily)
CrCl>50 mL/min (t =1417 hours) 3 days (skip 4 doses) 24 4872
CrCl 3050 mL/min (t =1618 hours) 45 days (skip 68 doses) 24 4872
CrCl 1530 mL/min (t =1618 hours)i 45 days (skip 68 doses) 24 4872
Rivaroxaban (20 mg once daily)
CrCl>50 mL/min (t =89 hours) 3 days (skip 2 doses) 24 4872
CrCl 3050 mL/min (t =9 hours) 3 days (skip 2 doses) 24 4872
CrCl 1529.9 mL/min (t =910 hours)j 4 days (skip 3 doses) 24 4872
Apixiban (5 mg twice daily)
CrCl>50 mL/min (t =78 hours) 3 days (skip 4 doses) 24 4872
CrCl 3050 mL/min (t =1718 hours) 4 days (skip 6 doses) 24 4872

ARE THERE INTERVENTIONS THAT CAN DECREASE THE RISK OF PERIPROCEDURAL BLEEDING AND/OR THROMBOEMBOLISM?

Mitigating the Risk of Bleeding

Bleeding complications can be reduced by allowing a sufficient time for the effects of antithrombotic medications to wear off before performing a procedure. This requires an understanding of the pharmacology of these medications, with particular attention to patients in whom these medications are less well studied, including the elderly, patients with renal insufficiency, and those with very high or low body mass index. Table 3 provides recommendations for when to stop antithrombotic therapy prior to an invasive procedure. The intervals are based on the time needed to achieve a minimal antithrombotic effect, which is generally 4 to 5 half‐lives for anticoagulants and 7 to 10 days for irreversible antiplatelet agents. Shorter intervals may be appropriate for procedures with low risk or consequence of bleeding, but there are insufficient data to make specific recommendations regarding this strategy.

It is equally important to ensure that there is adequate time for postoperative hemostasis prior to restarting antithrombotic therapy. Data from VTE prophylaxis trials and bridging studies consistently show that bleeding complications occur more frequently when anticoagulation is started too early, and antithrombotic therapy should generally be delayed 24 hours in patients at average risk and 48 to 72 hours in patients at high risk or consequence for postoperative bleeding.[8, 60, 65]

Aspirin increases the risk of surgical blood loss and transfusion by up to 20%, and by up to 50% when given in combination with clopidogrel, but with the exception of intracranial surgery, there does not appear to be an increase in perioperative morbidity or mortality with either of these agents.[66]

Mitigating the Risk of Thromboembolism

Once the decision has been made to temporarily discontinue warfarin, the next consideration is whether to bridge with a short acting anticoagulant (typically subcutaneous LMWH or intravenous UFH) during the period of time when the INR is subtherapeutic. Conceptually, one would expect this strategy would minimize the risk of thromboembolism, but its efficacy has never been clearly demonstrated. In fact, in a systematic review and meta‐analysis of 34 studies that compared the rates of thromboembolism among bridged and nonbridged patients, heparin therapy did not reduce the risk of thromboembolic events (odds ratio: 0.80; 95% confidence interval: 0.421.54), but did result in higher rates of periprocedural bleeding.[60]

The applicability of these results to clinical practice are limited by the heterogeneity of the data used in the analysis; specifically, bridging strategies varied (including therapeutic, intermediate, and prophylactic dose regimens), there was wide variation in the types of surgery (and therefore bleeding risk), and because the majority of studies were observational, there is a significant likelihood of confounding by indication (ie, patients at high risk for thromboembolism are more likely to receive bridging therapy), and thus the benefit of this strategy may be underestimated. It is also important to note that in the majority studies anticoagulation was restarted <24 hours after the procedure, which likely contributed to the increased rate of bleeding.

Therefore, although bridging therapy is not indicated for patients at low risk, it is premature to conclude that it should be avoided in patients at moderate or high risk for thromboembolism. The results of 2 ongoing, randomized, placebo‐controlled trials of bridging therapy in patients taking warfarin for atrial fibrillation (Effectiveness of Bridging Anticoagulation for Surgery [BRIDGE]) or mechanical heart values (A Double Blind Randomized Control Trial of Post‐Operative Low Molecular Weight Heparin Bridging Therapy Versus Placebo Bridging Therapy for Patients Who Are at High Risk for Arterial Thromboembolism [PERIOP‐2]) should help to answer this question.[67, 68]

The uncertainty regarding the benefits of bridging therapy is reflected in the changes to the most recent ACCP guidelines. In 2008, the ACCP recommended low‐dose LMWH or no bridging for patients at low risk (grade 2C), therapeutic‐dose bridging for patients at moderate risk (grade 2C), and therapeutic‐dose bridging for patients at high risk for thromboembolism (Grade 1C).[56] In 2012, the ACCP recommended against bridging for low‐risk patients (grade 2C), made no specific recommendation regarding moderate‐risk patients, and offered a less robust recommendation for bridging in high‐risk patients (grade 2C).[8]

Until the results of the BRIDGE and PERIOP‐2 trials are available, the author still favors therapeutic bridging for patients at high risk and selected patients at moderate risk for thromboembolism, provided sufficient time is allowed for postoperative hemostasis before anticoagulation is restarted. For procedures with a high risk or consequence of bleeding, intravenous UFH (without a bolus) is a reasonable initial postoperative strategy to insure that anticoagulation is tolerated before committing to LMWH. Indirect evidence supports the use of prophylactic or intermediate‐dose bridging regimens in patients for whom the primary consideration is the prevention of recurrent VTE, but data to show that this strategy is effective for the prevention of arterial thromboembolism are lacking.

Intravenous glycoprotein IIb/IIIa inhibitors are sometimes used to bridge high‐risk patients with coronary artery stents who must stop antiplatelet therapy prior to a procedure, but the data to support this practice are limited and observational in nature.[69, 70]

STARTING AND STOPPING ANTITHROMBOTIC THERAPY

Warfarin

For patients on warfarin, the INR at which it is safe to perform invasive procedures is unknown. Normal hemostasis requires clotting factor levels of approximately 20% to 40% of normal,[71] which generally corresponds to an INR of <1.5, whereas for most indications, therapeutic anticoagulation is achieved when the INR is between 2.0 and 3.5. However, because the relationship between the INR and the levels of clotting factors is nonlinear, for a given patient, the INR may be abnormal (ie, >1) despite levels of clotting factors that are sufficient for periprocedural hemostasis.[72, 73, 74, 75] Because of its relatively long half‐life (3642 hours), warfarin should be stopped 6 days (skip 5 doses) prior to a procedure to achieve an INR of <1.5, but can safely be restarted the same day in most patients.

Heparins

The half‐life of intravenous heparin is dose dependent, and at therapeutic levels is approximately 60 minutes; therefore, it should be discontinued 4 to 6 hours (5 half‐lives) before performing an invasive procedure.[76] The half‐life of subcutaneous LMWHs ranges from 3 to 7 hours in healthy volunteers,[23, 24, 25] and is often longer in patients for whom these medications are commonly prescribed.[77, 78] Therefore, when administered at therapeutic doses twice daily, the last dose should be given in the morning the day before the procedure, and for therapeutic once‐daily regimens, the last dose should be reduced by 50%.[8] The optimal time to discontinue prophylactic doses of LWMH prior to an invasive procedure is unclear, but a minimum of 12 hours is recommended.[22, 79] Because LWMHs are renally cleared, longer intervals are needed for patients with impaired renal function.[76, 80]

New Oral Anticoagulants

The manufacturer of rivaroxaban recommends that if anticoagulation must be discontinued, it be stopped at least 24 hours before the procedure.[81] Although this may be sufficient for procedures with a low risk or consequence of bleeding, the half‐life of rivaroxaban is between 8 and 10 hours, and therefore 48 hours (45 half‐lives) is required to ensure minimal residual anticoagulant effect.

Apixaban has a clearance half‐life of 6 hours, but displays prolonged absorption such that its effective half‐life is 12 hours after repeated dosing. The manufacturer recommends that it be stopped at least 24 hours prior to a procedure with a low risk or consequence of bleeding, and 48 hours prior to a procedure with a high risk or consequence of bleeding.[82]

The manufacturer of dabigatran recommends that the drug be discontinued 1 to 2 days (creatinine clearance (CrCl) 50 mL/min) or 3 to 5 days (CrCl <50 mL/min) before invasive or surgical procedures, and that longer times be considered when complete hemostasis is required.[83] Given that the half‐life of dabigatran is 14 to 17 hours, the author recommends that it be stopped at least 2 days (3 half‐lives) prior to a procedure with a low risk or consequence of bleeding, and 3 days (45 half‐lives) prior to a procedure with a high risk or consequence of bleeding.

The clearance of all the NOACs is significantly prolonged in patients with renal impairment, and a longer interval between the last dose and the procedure is necessary in patients with renal failure to ensure normal hemostasis (Table 3).

The effect of the NOACs on the standard clotting assays are complex and vary depending on drug dose, the type of reagents used, and the calibration of the equipment. For dabigatran, the activated partial thromboplastin time (aPTT) and the thrombin time (TT) are sufficiently sensitive to allow for a qualitative assessment of drug effect, such that a normal aPTT indicates the absence, or a very low level of an anticoagulant effect, and a normal TT essentially rules out an effect. Accurate quantitative testing of dabigatran requires an appropriately calibrated dilute thrombin test or ecarin clotting time assay.[84, 85]

Depending on the thromboplastin reagent used, the prothrombin time (PT) may be sufficiently sensitive to rivaroxaban that a normal level rules out a residual drug effect,[86] but this does not hold true for apixaban, which has minimal effect on the PT at therapeutic concentrations. The aPTT is insensitive to both rivaroxaban and apixaban and cannot be used for assessing residual drug effect. Accurate quantitative testing of rivaroxaban or apixaban requires an anti‐factor Xa assay calibrated for use with these agents.[84]

Antiplatelet Agents

Aspirin irreversibly inhibits platelet cyclooxygenase activity, and the thienopyridines clopidogrel and prasugrel, irreversibly inhibit the platelet P2Y12 receptor. As such, the biological effects of these medications persist until the platelet pool has turned over, a process that occurs at 10% to 12% per day and takes 7 to 10 days to complete.[87] The minimum number of functional platelets required to ensure adequate periprocedural hemostasis is unknown, but is likely between 50 and 100,000/L.[88] Therefore, assuming a platelet pool of 200,000/L, most patients will regenerate an adequate number of functional platelets by 5 days after discontinuing therapy, and nearly all will have normal platelet function by 10 days. Determining the risk of bleeding prior to complete turnover of the platelet pool is further complicated by genetic variability between patients in drug metabolism and the degree of platelet inhibition by these agents.[89]

Owing to this complexity, guidelines and prescribing recommendations are inconsistent. The ACCP recommends stopping antiplatelet agents 7 to 10 days prior to an invasive procedure, and the ACC/AHA makes no specific recommendations at all.[90] Based on data from patients undergoing cardiac bypass surgery, it is recommended that clopidogrel be stopped 5 days, and prasugrel 7 days, prior to an invasive procedure.[91, 92] The elimination half‐life of ticlodipine is sufficiently long (up to 96 hours after repeated dosing) that it should be stopped 10 to 14 days prior to an invasive procedure.[87] Ticagrelor is a reversible P2Y12 receptor inhibitor with a half‐life of approximately 8 hours and should therefore have minimal effect by 3 days after discontinuation; however, the manufacturer recommends that it be stopped 5 days prior to an invasive procedure.[93]

The optimal time to restart antiplatelet agents after an invasive procedure is also unknown. The 2008 ACCP guidelines recommended restarting aspirin and/or clopidogrel in 24 hours, or as hemostasis allows,[56] whereas neither the 2007 or 2009 ACC/AHA guidelines,[90] or the most recent 2012 ACCP guidelines,[8] offer specific recommendations. Aspirin, prasugrel, and ticagrelor have a rapid onset of action, whereas the full antiplatelet effect of clopidogrel does not occur for several days, and for patients in whom more rapid platelet inhibition is desired, a loading dose (300600 mg) may be appropriate.[87]

CONCLUSIONS

Deciding on an optimal periprocedural antithrombotic management strategy is a common challenge for hospitalists that requires careful consideration of both patient and procedure related‐risk factors for bleeding and thrombosis, as well as the consequences of delaying or forgoing the procedure altogether. For many procedures, there is evidence that antithrombotic therapy can be safely continued, thereby obviating the risk associated with interrupting therapy. When antithrombotic therapy must be stopped, it should be done in a manner that appropriately balances the risks and consequence of periprocedural bleeding and thromboembolism. Strategies to decrease the risk of perioperative bleeding include allowing sufficient time for the effects of antithrombotic therapy to subside before starting the procedure, and ensuring adequate time for hemostasis before restarting antithrombotic therapy. Bridging therapy may provide net clinical benefit for patients at moderate to high risk for thromboembolism, but this will not be clear until the results of several ongoing bridging trials are available. The periprocedural antithrombotic management strategy should be developed in collaboration with the relevant providers and with active participation by the patient in all decisions and treatment plans. Standardized protocols and documentation can help to minimize unintended variation in practice and improve information transfer during transitions of care.

Acknowledgements

The author would like to thank Shoshana and Lola Herzig for their support in the design and preparation of the manuscript.

Disclosure: Nothing to report.

The periprocedural management of antithrombotic medications is a common challenge for hospitalists, for which there is limited high‐quality evidence to guide clinical decision making. The introduction of third‐generation antiplatelet agents (prasugrel and ticagrelor) and the new oral anticoagulants (rivaroxaban, apixaban, and dabigatran), has added an additional layer of complexity to clinical management.

This article will provide a conceptual framework for the periprocedural management of antithrombotic therapy, with a particular focus on procedures that are considered core competencies by the Society of Hospital Medicine; these include: arthrocentesis, lumbar puncture, paracentesis, thoracentesis, and central line placement (Table 1).[1, 2] The recommendations in this article are based on a review of published guidelines and consensus statements and their supporting literature.[3, 4, 5, 6, 7, 8] Additional articles were identified by performing a PubMed keyword search using the terms perioperative management or periprocedural management and anticoagulation or antithrombotic or antiplatelet in combination with keywords relevant to the content areas (eg, arthrocentesis, lumbar puncture). Articles for inclusion were chosen based on methodological quality and relevance to hospital medicine.

There are several questions that must be addressed when developing a periprocedural antithrombotic management strategy:

  1. What is the patient's risk of bleeding if antithrombotic therapy is continued?
  2. What is the patient's risk of thromboembolism if antithrombotic therapy is interrupted?
  3. Are there interventions that can decrease the risk of periprocedural bleeding and/or thromboembolism?

WHAT IS THE PATIENT'S RISK OF BLEEDING IF ANTITHROMBOTIC THERAPY IS CONTINUED?

Although the risk of bleeding is well described for many procedures, there are limited data on how that risk is affected by coagulopathy in general and antithrombotic medications in particular. When these data are available, they are largely derived from case series or bridging registries, which include heterogeneous patient populations and nonstandardized definitions of bleeding.[8, 9, 10] As such, few procedural or surgical professional societies have published guidelines on the periprocedural management of antithrombotic therapy,[3, 4, 5, 11]and guidelines from the American College of Chest Physicians (ACCP), the American College of Cardiology (ACC), and American Heart Association (AHA) only provide specific recommendations regarding minor ambulatory procedures.[6, 7, 8]

Procedures can be categorized as low or high risk for bleeding based on the following considerations: the extent of associated tissue injury, proximity to vital organs or vascular structures, the ability to readily detect and control bleeding, and the morbidity associated with a bleeding complication (eg, a small bleed into the epidural space is potentially catastrophic, whereas a large bleed from the colon often results in no permanent harm). For procedures with a high risk or consequence of bleeding, anticoagulants must be stopped, whereas in some cases antiplatelet agents can be safely continued. For procedures with a low risk or consequence of bleeding, it may be possible to continue both anticoagulant and antiplatelet agents.

Recommended Periprocedural Management of Antithrombotic Therapy
Procedure Antithrombotic Therapy
Aspirin Thienopyridines Prophylactic UFH or LWMH Therapeutic UFH or LMWH Warfarin NOACs
  • NOTE:+= safe to continue during procedure;= unsafe to continue during procedure;= insufficient data, individualized approach recommended. Abbreviations: BID, twice daily; LMWH, low‐molecular‐weight heparin; NOACs, new oral anticoagulants (rivaroxaban, apixiban, dabigatran); UFH, unfractionated heparin.

Arthrocentesis[12, 13, 14, 15] + + + + + +
Lumbar puncture[3] + 5000 units UFH BID
Paracentesis[28, 29, 30] + + +
Thoracentesis[37, 38, 39, 40, 41, 42] + + +
Central venous catheter insertion[48, 49, 50, 51, 52, 53] + + +

Because procedures in hospitalized patients are most often performed for the purpose of diagnosing or treating an emergent condition, the risk of delaying the procedure while antithrombotic medications are held must be part of the overall risk‐benefit calculation.

Arthrocentesis

Bleeding complications from arthrocentesis are very rare, and there are few data on the additional risk associated with antithrombotic therapy.[12, 13, 14] In a retrospective cohort study, investigators determined the incidence of clinically significant bleeding (defined as bleeding requiring reversal of anticoagulation, prolonged manual pressure, surgical intervention, hospital admission, or delay in hospital discharge) and procedure‐related pain among 514 patients on antithrombotic therapy referred for arthrocentesis or injection of the hip, shoulder, or knee. Four hundred fifty‐six procedures were performed in patients without interrupting warfarin therapy, all of whom maintained an international normalized ratio (INR)2, and 184 procedures were performed in patients who had stopped their warfarin to achieve an INR <2. Antiplatelet therapy was routinely continued in both groups, with 48% of patients taking aspirin and 9% clopidogrel. There was 1 bleeding complication (0.2%) in a patient with an INR of 2.3 who was also taking aspirin, and 2 patients developed procedure‐related pain (INR 3.3 and 5.3, neither taking antiplatelet medications).[15]

Based on the available evidence, arthrocentesis appears to be safe in patients on therapeutic warfarin, with or without aspirin and/or clopidogrel. At present, there are no published studies that address the risk of arthrocentesis in patients taking other antiplatelet or anticoagulant medications, but given the low overall risk of this procedure, it is reasonable to infer that these medications can also be safely continued.

Lumbar Puncture

The incidence of bleeding complications from diagnostic lumbar puncture is unknown, but is likely similar to that seen with spinal anesthesia, where in a large retrospective observational study, spinal hematoma occurred in 1:165,000 spinal block procedures.[16] Factors associated with an increased risk of spinal hematoma include traumatic tap, advanced age, female gender, spinal cord or vertebral column abnormalities, coagulopathy, and not allowing sufficient time between stopping and restarting antithrombotic therapy.[3, 17, 18, 19, 20]

Therapeutic anticoagulation must be stopped and prophylactic anticoagulation delayed before performing a lumbar puncture. The 1 exception is low‐dose unfractionated heparin (UFH), which the American Society for Regional Anesthesia (ARSA) recommends continuing in patients undergoing neuraxial procedures, provided the total dose is 5000 U twice daily. This assessment is based on observational data, surveys of practice patterns, and decades of use without evidence of complications; in fact, there are only 5 case reports of spinal hematomas in this population.[3] However, because these data are from surgical populations, in which heparin thromboprophylaxis is typically dosed at 5000 units twice daily, there are limited data on the safety of higher or more frequent doses of heparin. In a retrospective cohort study of 928 patients who received thoracic epidural analgesia in conjunction with UFH dosed at 5000 U, 3 times daily, there were no cases of neuraxial bleeding, but given the rarity of neuraxial hematoma, it is not possible to draw any conclusions from this relatively small sample size.[21]

In November 2013, based on surveillance data showing increased risk for spinal or epidural hematoma associated with low‐molecular‐weight heparin (LMWH), the US Food and Drug Administration (FDA) issued a drug safety communication recommending that neuraxial procedures be delayed for 12 hours after prophylactic LMWH and 24 hours after therapeutic LMWH, and that LMWH not be restarted for at least 4 hours after catheter removal.[20] These recommendations are largely consistent with existing guidelines[3, 22] but are not explicitly stated in the package insert for any of the LMWHs available in the United States,[23, 24, 25] and the FDA is working with the manufacturers to add this information.

Nonsteroidal anti‐inflammatory drugs (NSAIDs), dipyridamole, and aspirin do not appear to increase the risk of spinal hematoma and are considered safe to continue.[11, 26] There are limited data on the safety of thienopyridine medications in neuraxial anesthesia, but based on case reports and increased bleeding rates seen in surgical populations, it is generally recommended that these medications be discontinued before performing a lumbar puncture.[3, 22, 27]

The optimal time to restart anticoagulation after a lumbar puncture is unknown. The ARSA recommends a minimum of 1 hour for UFH and 2 hours for LMWH after neuraxial catheter removal, and provides no specific guidance about other anticoagulants,[3] whereas the European Society of Anesthesiology recommends a minimum of 1 hour for UFH, 4 hours for LMWH, 4 to 6 hours for rivaroxaban and apixiban, and 6 hours for dabigatran and fondaparinux.[22] Longer time periods should be considered after a traumatic tap, and postprocedure monitoring of neurological function is recommended for all patients.

The available evidence suggests that lumbar puncture can be safely performed in patients being treated with aspirin, NSAIDs, and UFH dosed at 5000 U twice daily; the safety of higher or more frequent doses of UFH is not known. Lumbar puncture should be delayed 12 hours after prophylactic LMWH and 24 hours after therapeutic LMWH, and LMWH should not be restarted for at least 4 hours after the procedure.[20] There are limited data on the safety of thienopyridines, but they should generally be discontinued, and all other prophylactic or therapeutic anticoagulation must be stopped prior to the procedure.

Paracentesis

Bleeding complications from paracentesis are uncommon, with abdominal wall hematoma and hemoperitoneum complicating 1% and 0.01% of procedures, respectively.[28, 29, 30] Whether antithrombotic therapy increases the risk of bleeding during paracentesis is unknown, primarily because most patients for whom the procedure is indicated have coagulopathy and thrombocytopenia from liver disease, and are therefore rarely treated with these medications.

Although patients with liver disease often have an elevated INR due to impaired hepatic synthesis of clotting factors, it is incorrect to generalize the observed rate of bleeding in this population to patients with an elevated INR from warfarin therapy who may require paracentesis for reasons unrelated to liver disease (eg, malignancy or infection). The coagulopathy of liver disease reflects deficiencies in the hepatic production of both pro‐ and anticoagulant proteins, and these patients develop both thrombotic and hemorrhagic complications irrespective of their in vitro coagulation indices.[31]

Although the available evidence suggests that paracentesis can be safely performed in patients with coagulopathy from liver disease, regardless of the INR,[30] little is known about the bleeding risk in other patients, with or without antithrombotic therapy. Based on indirect evidence, it is reasonable to assume that prophylactic UFH or LWMH or antiplatelet therapy would confer minimal additional risk, whereas the safety of continuing therapeutic anticoagulation is unknown.

Thoracentesis

Bleeding complications from thoracentesis are uncommon, generally occurring in <1% of procedures.[32, 33, 34] Factors associated with increased risk of overall complications include operator inexperience, large volume drainage, and lack of ultrasound guidance.[34, 35, 36] There are no studies that specifically address the risk of bleeding in patients on anticoagulant therapy, but such patients are included in studies on the risk of bleeding with coagulopathy.[37, 38, 39, 40]

In a retrospective cohort study of 1076 ultrasound‐guided thoracenteses performed by radiologists on patients with coagulopathy (defined as thrombocytopenia or an elevated INR from any cause), there were no bleeding complications (defined as anything other than minimal symptoms not requiring intervention). Among the patients in this study, 497 (46%) patients had a preprocedure INR >1.5; 198 (24%) had an INR between 2 and 3, and 32 (4%) had an INR >3.[39]

A similar study, which compared outcomes in patients with corrected and uncorrected coagulopathy, included 744 patients with an INR >1.6 (from any cause), of which 167 received preprocedural fresh‐frozen plasma (FFP) and 577 did not. There was 1 (0.1%) bleeding complication in a patient who received prophylactic FFP and none in the group that was not transfused.[38]

In a prospective cohort of 312 patients at increased risk for bleeding (from coagulopathy or antithrombotic medications) who underwent ultrasound‐guided thoracentesis by a pulmonologist or physician's assistant, 44 (34%) had an INR >1.5 (secondary to liver disease or warfarin therapy), 15 (12%) were taking clopidogrel, and 14 (11%) were treated with therapeutic LMWH within 12 hours or therapeutic UFH within 4.5 hours of the procedure. There were no bleeding complications in any of the patients (defined as mean change in hematocrit, chest x‐ray abnormalities, hemothorax, or requirement for transfusion).[37]

Although there are no studies that specifically address the use of aspirin and bleeding complications in thoracentesis, it is generally considered safe to continue this medication,[5] and there are small studies that show that thoracentesis and small‐bore chest tubes can be safely placed in patients taking clopidogrel.[41, 42]

Thoracentesis is associated with a low rate of bleeding complications, and when performed by an experienced operator using ultrasound, warfarin does not appear to increase this risk. However, given the low overall complication rate, it is not known whether patients on warfarin would have worse outcomes in the event of more serious complications (eg, intercostal artery laceration). At present, there are no published studies that address the risk of thoracentesis in patients taking new oral anticoagulants (NOACs).

Central Venous Catheter Insertion

The incidence of bleeding complications from central venous catheter (CVC) placement varies depending on the site of insertion and definition of bleeding, with hematoma and hemothorax occurring in 0.1% to 6.9%, and 0.4% to 1.3% of procedures, respectively.[43, 44, 45] Factors that increase the likelihood of complications include operator inexperience, multiple needle passes, and lack of ultrasound guidance.[46, 47] There are no studies that specifically address the risk of bleeding from CVC placement in patients on anticoagulant therapy, but such patients are included in studies of CVC placement in patients with coagulopathy, which report similar complication rates as seen in patients with normal hemostasis.[48, 49, 50, 51, 52, 53]

In a retrospective cohort study, investigators collected information on CVC‐associated bleeding complications in 281 medical and surgical intensive care patients with coagulopathy (INR 1.5 from any cause) after they adopted a more conservative approach to plasma transfusion in their intensive care unit; specifically, the routine use of prophylactic FFP to correct coagulopathy was discouraged for patients with an INR <3 (vs usual practice using an INR cutoff of 1.5), but the final decision was left to the discretion of the attending performing or supervising the procedure. Bleeding was defined as insertion‐site hematoma, interventions other than local manual pressure, and the need for blood transfusion. One case of bleeding (hematoma) was observed in a patient with an INR of 3.9, who received FFP before the procedure. There were no complications among those with uncorrected coagulopathy, including 66 patients with an INR between 1.5 and 2.9, and 6 with an INR 3.0. Ultrasound guidance was used in 50% of CVCs placed in the internal jugular vein.[54]

Although there are no studies that specifically address the use of antiplatelet drugs and bleeding complications in CVC placement, aspirin is generally considered safe to continue,[5] and by inference, thienopyridines are expected to add minimal additional risk.

CVC placement is associated with a variable rate of bleeding complications, with hematoma being relatively common. Based on the available literature, warfarin does not appear to increase this risk, but there are limited data from which to draw firm conclusions. A femoral or jugular approach may be preferable because they allow for ultrasound visualization and are amenable to manual compression. There are no published studies that address the risk of CVC placement in patients taking NOACs, and although the risk of bleeding is probably similar to patients receiving warfarin, the lack of effective reversal agents for these medications should be part of any risk‐benefit calculation.[55]

WHAT IS THE PATIENT'S RISK OF THROMBOEMBOLISM IF ANTITHROMBOTIC THERAPY IS INTERRUPTED?

Anticoagulants

If it is determined that a procedure cannot safely be performed while continuing antithrombotic therapy, one must then consider the patient's risk of thromboembolism if these therapies are temporarily interrupted. Unfortunately, there are few robust clinical studies from which to make this assessment, and therefore most clinicians rely on the risk stratification model proposed by the ACCP, which divides patients into 3 tiers (low, moderate, high), based on their indication for anticoagulation and risk factors for thromboembolism (Table 2)[8]. The ACCP model is largely based on indirect evidence from antithrombotic therapy trials in nonoperative patients, and its application to perioperative patients necessitates several assumptions that may not hold true in practice.

American College of Chest Physicians Stratification for Perioperative Thromboembolism
Indication for Anticoagulant Therapy
Risk Stratum Mechanical Heart Valve Atrial Fibrillation VTE
  • NOTE: Abbreviations: CHADS2=congestive heart failure, hypertension, age 75 years, diabetes mellitus, and stroke or transient ischemic attack; TIA, transient ischemic attack; VKA, vitamin K antagonist; VTE, venous thromboembolism.

  • High‐risk patients may also include those with a prior stroke or TIA occurring >3 months before the planned surgery and a CHADS2 score <5, those with prior thromboembolism during temporary interruption of VKAs, or those undergoing certain types of surgery associated with an increased risk for stroke or other thromboembolism (eg, cardiac valve replacement, carotid endarterectomy, major vascular surgery).

High Thrombotic Risk
  • Any mitral valve prosthesis
  • Any caged‐ball or tilting disc aortic valve prosthesis
  • Recent (within 6 months) stroke or TIA
  • CHADS2 score of 5 or 6
  • Recent (within 3 months) stroke or TIA
  • Rheumatic valvular heart disease
  • Recent (within 3 months) VTE
  • Severe thrombophilia (eg, deficiency of protein C, protein S, or antithrombin; antiphospholipid antibodies; multiple abnormalities)
Moderate Thrombotic Risk
  • Bileaflet aortic valve prosthesis with one or more of the following risk factors: atrial fibrillation, prior stroke or TIA, hypertension, diabetes, congestive heart failure, age 75 years
  • CHADS2 score of 3 or 4
  • VTE within the past 3 to 12 months
  • Nonsevere thrombophilia (eg, heterozygous factor V Leiden or prothrombin gene mutation)
  • Recurrent VTE
  • Active cancer (treated within six months or palliative)
Low Thrombotic Risk
  • Bileaflet aortic valve prosthesis without atrial fibrillation and no other risk factors for stroke
  • CHADS2 score of 0 to 2 (assuming no prior stroke or TIA)
  • VTE >12 months previous and no other risk factors

First, it assumes that the annualized risk of a thrombotic event in nonoperative patients can be prorated to determine the short‐term risk of discontinuing antithrombotic therapy in the perioperative period. For example, it has been estimated that the risk for perioperative stroke in a patient with atrial fibrillation who temporarily interrupts anticoagulation for 1 week would be 0.1% (5% per year 52 weeks),[56, 57]and yet we know from observational data that the actual risk of perioperative stroke in similar patients is 5 to 7 times higher.[58, 59] Second, it assumes that bridging therapy will decrease the risk of thromboembolism in high‐risk patients when warfarin therapy is interrupted, a premise that is logical but has not been subject to randomized controlled trials.[60] Third, it does not take into account the surgery‐specific risk for thromboembolism, which varies significantly, with arterial thromboembolism being more common in cardiac valve, vascular, and neurologic procedures, and venous thromboembolism (VTE) being more likely in orthopedic, trauma, and cancer surgery.[61, 62] These limitations notwithstanding, the ACCP model still offers the best available framework for thrombotic risk assessment and a reasonable starting point for clinical decision making.

Antiplatelet Agents

Patients with coronary artery stents who undergo noncardiac surgery are at increased risk for adverse cardiovascular events, including acute stent thrombosis, which carries a risk of myocardial infarction and death of 70% and 30%, respectively.[63] This risk is highest during the period between stent implantation and endothelialization, a process that takes 4 to 6 weeks for bare‐metal stents (BMS) and 6 to 12 months for drug‐eluting stents (DES). Premature discontinuation of dual antiplatelet therapy is the most important risk factor for stent thrombosis during this time.[64] Although the optimal perioperative strategy for these patients is unknown, there is general agreement that elective surgery should be delayed for at least 4 weeks in patients with a BMS and 12 months for patients with a DES. If a procedure or surgery is required during this time period, every effort should be made to continue dual antiplatelet therapy; if this is not possible, aspirin should be continued, and thienopyridine therapy should be interrupted as briefly as possible (Table 3).

Recommended Timing for Periprocedural Interruption and Initiation of Antithrombotic Therapy
Recommended Interval Between Last Dose of Medication and Procedure Recommended Interval Between Procedure and First Dose of Medication, h
Low Risk or Consequence of Postprocedure Bleeding High Risk or Consequence of Postprocedure Bleeding
  • NOTE: Abbreviations: CrCl, creatinine clearance; LMWH, low‐molecular‐weight heparin; UFH, unfractionated heparin.

  • Assuming minimal platelet effect by 7 days and no effect by 10 days for (irreversible) agents: aspirin, ticlodipine, clopidogrel, and prasugrel. Ticlodipine drug clearance is prolonged by an additional 4 days after repeated dosing.

  • Ticagrelor and cilostazol half‐life depends on rate of drug clearance.

  • Five days is sufficient for cardiac surgery.[94]

  • Seven days per manufacturer[91]; drug effect may persist up to 10 days.

  • Five days per manufacturer[93]; a shorter interval is expected based on half‐life.

  • Intervals based on 45 drug half‐lives to achieve minimal residual anticoagulant effect; shorter intervals may be appropriate for procedures with low risk or consequence of bleeding. Adapted from Spyropoulos and Douketis.[95]

  • More than 90% of patients will achieve an international normalized ratio <1.5 after skipping 5 doses.[8]

  • Longer intervals are recommended for patients with CrCl <30 mL/min.[96]

  • Longer intervals are recommended for patients with CrCl <50 mL/min.[96]

  • Patients receiving dabigatran 75 mg twice daily.

  • Patients receiving rivaroxaban 15 mg daily.

Antiplatelet Medicationsa
Aspirin (81325 mg dailydipyridamole) 710 days (skip 69 doses) 24 48
Ticlodipine (250 mg twice daily) 1014 days (skip 1926 doses) 24 48
Clopidogrel (75 mg once daily) 710 days (skip 69 doses)b 24 48
Prasugrel (10 mg once daily) 710 days (skip 69 dose)c 24 48
Ticagrelor (90 mg twice daily; t =8 hours) 5 days (skip 8 doses) 24 48
Cilostazol (100 mg twice daily; t =11 hours) 3 days (skip 4 doses) 24 48
Anticoagulant Medicationse
Warfarin (t =3642 hours, but highly variable) 6 days (skip 5 doses)f 12 24
Intravenous UFH (t 60 minutes) 46 hours 24 4872
LMWH (t =37 hours)
Prophylactic dosing 12 hours# 12 2436
Therapeutic dosing
Once daily 24 hours (give 50% of last total dose)# 24 4872
Twice daily 24 hours (skip 1 dose)# 24 4872
Fondaparinux (t =17 hours, any dose) 34 days (skip 23 doses)h 24 4872
Dabigatran (150 mg twice daily)
CrCl>50 mL/min (t =1417 hours) 3 days (skip 4 doses) 24 4872
CrCl 3050 mL/min (t =1618 hours) 45 days (skip 68 doses) 24 4872
CrCl 1530 mL/min (t =1618 hours)i 45 days (skip 68 doses) 24 4872
Rivaroxaban (20 mg once daily)
CrCl>50 mL/min (t =89 hours) 3 days (skip 2 doses) 24 4872
CrCl 3050 mL/min (t =9 hours) 3 days (skip 2 doses) 24 4872
CrCl 1529.9 mL/min (t =910 hours)j 4 days (skip 3 doses) 24 4872
Apixiban (5 mg twice daily)
CrCl>50 mL/min (t =78 hours) 3 days (skip 4 doses) 24 4872
CrCl 3050 mL/min (t =1718 hours) 4 days (skip 6 doses) 24 4872

ARE THERE INTERVENTIONS THAT CAN DECREASE THE RISK OF PERIPROCEDURAL BLEEDING AND/OR THROMBOEMBOLISM?

Mitigating the Risk of Bleeding

Bleeding complications can be reduced by allowing a sufficient time for the effects of antithrombotic medications to wear off before performing a procedure. This requires an understanding of the pharmacology of these medications, with particular attention to patients in whom these medications are less well studied, including the elderly, patients with renal insufficiency, and those with very high or low body mass index. Table 3 provides recommendations for when to stop antithrombotic therapy prior to an invasive procedure. The intervals are based on the time needed to achieve a minimal antithrombotic effect, which is generally 4 to 5 half‐lives for anticoagulants and 7 to 10 days for irreversible antiplatelet agents. Shorter intervals may be appropriate for procedures with low risk or consequence of bleeding, but there are insufficient data to make specific recommendations regarding this strategy.

It is equally important to ensure that there is adequate time for postoperative hemostasis prior to restarting antithrombotic therapy. Data from VTE prophylaxis trials and bridging studies consistently show that bleeding complications occur more frequently when anticoagulation is started too early, and antithrombotic therapy should generally be delayed 24 hours in patients at average risk and 48 to 72 hours in patients at high risk or consequence for postoperative bleeding.[8, 60, 65]

Aspirin increases the risk of surgical blood loss and transfusion by up to 20%, and by up to 50% when given in combination with clopidogrel, but with the exception of intracranial surgery, there does not appear to be an increase in perioperative morbidity or mortality with either of these agents.[66]

Mitigating the Risk of Thromboembolism

Once the decision has been made to temporarily discontinue warfarin, the next consideration is whether to bridge with a short acting anticoagulant (typically subcutaneous LMWH or intravenous UFH) during the period of time when the INR is subtherapeutic. Conceptually, one would expect this strategy would minimize the risk of thromboembolism, but its efficacy has never been clearly demonstrated. In fact, in a systematic review and meta‐analysis of 34 studies that compared the rates of thromboembolism among bridged and nonbridged patients, heparin therapy did not reduce the risk of thromboembolic events (odds ratio: 0.80; 95% confidence interval: 0.421.54), but did result in higher rates of periprocedural bleeding.[60]

The applicability of these results to clinical practice are limited by the heterogeneity of the data used in the analysis; specifically, bridging strategies varied (including therapeutic, intermediate, and prophylactic dose regimens), there was wide variation in the types of surgery (and therefore bleeding risk), and because the majority of studies were observational, there is a significant likelihood of confounding by indication (ie, patients at high risk for thromboembolism are more likely to receive bridging therapy), and thus the benefit of this strategy may be underestimated. It is also important to note that in the majority studies anticoagulation was restarted <24 hours after the procedure, which likely contributed to the increased rate of bleeding.

Therefore, although bridging therapy is not indicated for patients at low risk, it is premature to conclude that it should be avoided in patients at moderate or high risk for thromboembolism. The results of 2 ongoing, randomized, placebo‐controlled trials of bridging therapy in patients taking warfarin for atrial fibrillation (Effectiveness of Bridging Anticoagulation for Surgery [BRIDGE]) or mechanical heart values (A Double Blind Randomized Control Trial of Post‐Operative Low Molecular Weight Heparin Bridging Therapy Versus Placebo Bridging Therapy for Patients Who Are at High Risk for Arterial Thromboembolism [PERIOP‐2]) should help to answer this question.[67, 68]

The uncertainty regarding the benefits of bridging therapy is reflected in the changes to the most recent ACCP guidelines. In 2008, the ACCP recommended low‐dose LMWH or no bridging for patients at low risk (grade 2C), therapeutic‐dose bridging for patients at moderate risk (grade 2C), and therapeutic‐dose bridging for patients at high risk for thromboembolism (Grade 1C).[56] In 2012, the ACCP recommended against bridging for low‐risk patients (grade 2C), made no specific recommendation regarding moderate‐risk patients, and offered a less robust recommendation for bridging in high‐risk patients (grade 2C).[8]

Until the results of the BRIDGE and PERIOP‐2 trials are available, the author still favors therapeutic bridging for patients at high risk and selected patients at moderate risk for thromboembolism, provided sufficient time is allowed for postoperative hemostasis before anticoagulation is restarted. For procedures with a high risk or consequence of bleeding, intravenous UFH (without a bolus) is a reasonable initial postoperative strategy to insure that anticoagulation is tolerated before committing to LMWH. Indirect evidence supports the use of prophylactic or intermediate‐dose bridging regimens in patients for whom the primary consideration is the prevention of recurrent VTE, but data to show that this strategy is effective for the prevention of arterial thromboembolism are lacking.

Intravenous glycoprotein IIb/IIIa inhibitors are sometimes used to bridge high‐risk patients with coronary artery stents who must stop antiplatelet therapy prior to a procedure, but the data to support this practice are limited and observational in nature.[69, 70]

STARTING AND STOPPING ANTITHROMBOTIC THERAPY

Warfarin

For patients on warfarin, the INR at which it is safe to perform invasive procedures is unknown. Normal hemostasis requires clotting factor levels of approximately 20% to 40% of normal,[71] which generally corresponds to an INR of <1.5, whereas for most indications, therapeutic anticoagulation is achieved when the INR is between 2.0 and 3.5. However, because the relationship between the INR and the levels of clotting factors is nonlinear, for a given patient, the INR may be abnormal (ie, >1) despite levels of clotting factors that are sufficient for periprocedural hemostasis.[72, 73, 74, 75] Because of its relatively long half‐life (3642 hours), warfarin should be stopped 6 days (skip 5 doses) prior to a procedure to achieve an INR of <1.5, but can safely be restarted the same day in most patients.

Heparins

The half‐life of intravenous heparin is dose dependent, and at therapeutic levels is approximately 60 minutes; therefore, it should be discontinued 4 to 6 hours (5 half‐lives) before performing an invasive procedure.[76] The half‐life of subcutaneous LMWHs ranges from 3 to 7 hours in healthy volunteers,[23, 24, 25] and is often longer in patients for whom these medications are commonly prescribed.[77, 78] Therefore, when administered at therapeutic doses twice daily, the last dose should be given in the morning the day before the procedure, and for therapeutic once‐daily regimens, the last dose should be reduced by 50%.[8] The optimal time to discontinue prophylactic doses of LWMH prior to an invasive procedure is unclear, but a minimum of 12 hours is recommended.[22, 79] Because LWMHs are renally cleared, longer intervals are needed for patients with impaired renal function.[76, 80]

New Oral Anticoagulants

The manufacturer of rivaroxaban recommends that if anticoagulation must be discontinued, it be stopped at least 24 hours before the procedure.[81] Although this may be sufficient for procedures with a low risk or consequence of bleeding, the half‐life of rivaroxaban is between 8 and 10 hours, and therefore 48 hours (45 half‐lives) is required to ensure minimal residual anticoagulant effect.

Apixaban has a clearance half‐life of 6 hours, but displays prolonged absorption such that its effective half‐life is 12 hours after repeated dosing. The manufacturer recommends that it be stopped at least 24 hours prior to a procedure with a low risk or consequence of bleeding, and 48 hours prior to a procedure with a high risk or consequence of bleeding.[82]

The manufacturer of dabigatran recommends that the drug be discontinued 1 to 2 days (creatinine clearance (CrCl) 50 mL/min) or 3 to 5 days (CrCl <50 mL/min) before invasive or surgical procedures, and that longer times be considered when complete hemostasis is required.[83] Given that the half‐life of dabigatran is 14 to 17 hours, the author recommends that it be stopped at least 2 days (3 half‐lives) prior to a procedure with a low risk or consequence of bleeding, and 3 days (45 half‐lives) prior to a procedure with a high risk or consequence of bleeding.

The clearance of all the NOACs is significantly prolonged in patients with renal impairment, and a longer interval between the last dose and the procedure is necessary in patients with renal failure to ensure normal hemostasis (Table 3).

The effect of the NOACs on the standard clotting assays are complex and vary depending on drug dose, the type of reagents used, and the calibration of the equipment. For dabigatran, the activated partial thromboplastin time (aPTT) and the thrombin time (TT) are sufficiently sensitive to allow for a qualitative assessment of drug effect, such that a normal aPTT indicates the absence, or a very low level of an anticoagulant effect, and a normal TT essentially rules out an effect. Accurate quantitative testing of dabigatran requires an appropriately calibrated dilute thrombin test or ecarin clotting time assay.[84, 85]

Depending on the thromboplastin reagent used, the prothrombin time (PT) may be sufficiently sensitive to rivaroxaban that a normal level rules out a residual drug effect,[86] but this does not hold true for apixaban, which has minimal effect on the PT at therapeutic concentrations. The aPTT is insensitive to both rivaroxaban and apixaban and cannot be used for assessing residual drug effect. Accurate quantitative testing of rivaroxaban or apixaban requires an anti‐factor Xa assay calibrated for use with these agents.[84]

Antiplatelet Agents

Aspirin irreversibly inhibits platelet cyclooxygenase activity, and the thienopyridines clopidogrel and prasugrel, irreversibly inhibit the platelet P2Y12 receptor. As such, the biological effects of these medications persist until the platelet pool has turned over, a process that occurs at 10% to 12% per day and takes 7 to 10 days to complete.[87] The minimum number of functional platelets required to ensure adequate periprocedural hemostasis is unknown, but is likely between 50 and 100,000/L.[88] Therefore, assuming a platelet pool of 200,000/L, most patients will regenerate an adequate number of functional platelets by 5 days after discontinuing therapy, and nearly all will have normal platelet function by 10 days. Determining the risk of bleeding prior to complete turnover of the platelet pool is further complicated by genetic variability between patients in drug metabolism and the degree of platelet inhibition by these agents.[89]

Owing to this complexity, guidelines and prescribing recommendations are inconsistent. The ACCP recommends stopping antiplatelet agents 7 to 10 days prior to an invasive procedure, and the ACC/AHA makes no specific recommendations at all.[90] Based on data from patients undergoing cardiac bypass surgery, it is recommended that clopidogrel be stopped 5 days, and prasugrel 7 days, prior to an invasive procedure.[91, 92] The elimination half‐life of ticlodipine is sufficiently long (up to 96 hours after repeated dosing) that it should be stopped 10 to 14 days prior to an invasive procedure.[87] Ticagrelor is a reversible P2Y12 receptor inhibitor with a half‐life of approximately 8 hours and should therefore have minimal effect by 3 days after discontinuation; however, the manufacturer recommends that it be stopped 5 days prior to an invasive procedure.[93]

The optimal time to restart antiplatelet agents after an invasive procedure is also unknown. The 2008 ACCP guidelines recommended restarting aspirin and/or clopidogrel in 24 hours, or as hemostasis allows,[56] whereas neither the 2007 or 2009 ACC/AHA guidelines,[90] or the most recent 2012 ACCP guidelines,[8] offer specific recommendations. Aspirin, prasugrel, and ticagrelor have a rapid onset of action, whereas the full antiplatelet effect of clopidogrel does not occur for several days, and for patients in whom more rapid platelet inhibition is desired, a loading dose (300600 mg) may be appropriate.[87]

CONCLUSIONS

Deciding on an optimal periprocedural antithrombotic management strategy is a common challenge for hospitalists that requires careful consideration of both patient and procedure related‐risk factors for bleeding and thrombosis, as well as the consequences of delaying or forgoing the procedure altogether. For many procedures, there is evidence that antithrombotic therapy can be safely continued, thereby obviating the risk associated with interrupting therapy. When antithrombotic therapy must be stopped, it should be done in a manner that appropriately balances the risks and consequence of periprocedural bleeding and thromboembolism. Strategies to decrease the risk of perioperative bleeding include allowing sufficient time for the effects of antithrombotic therapy to subside before starting the procedure, and ensuring adequate time for hemostasis before restarting antithrombotic therapy. Bridging therapy may provide net clinical benefit for patients at moderate to high risk for thromboembolism, but this will not be clear until the results of several ongoing bridging trials are available. The periprocedural antithrombotic management strategy should be developed in collaboration with the relevant providers and with active participation by the patient in all decisions and treatment plans. Standardized protocols and documentation can help to minimize unintended variation in practice and improve information transfer during transitions of care.

Acknowledgements

The author would like to thank Shoshana and Lola Herzig for their support in the design and preparation of the manuscript.

Disclosure: Nothing to report.

References
  1. Dressler DD, Pistoria MJ, Budnitz TL, McKean SC, Amin AN. Core competencies in hospital medicine: development and methodology. J Hosp Med. 2006;1(suppl 1):4856.
  2. Thakkar R, Wright SM, Alguire P, Wigton RS, Boonyasai RT. Procedures performed by hospitalist and non‐hospitalist general internists. J Gen Int Med. 2010;25(5):448452.
  3. Horlocker TT, Wedel DJ, Rowlingson JC, et al. Regional anesthesia in the patient receiving antithrombotic or thrombolytic therapy: American Society of Regional Anesthesia and Pain Medicine evidence‐based guidelines (Third Edition). Reg Anesth Pain Med. 2010;35(1):64101.
  4. ASGE Standards of Practice Committee, Anderson MA, Ben‐Menachem T, Gan SI, et al. Management of antithrombotic agents for endoscopic procedures. Gastrointest Endosc. 2009;70(6):10601070.
  5. Patel IJ, Davidson JC, Nikolic B, et al. Consensus guidelines for periprocedural management of coagulation status and hemostasis risk in percutaneous image‐guided interventions. J Vasc Interv Radiol. 2012;23(6):727736.
  6. Bonow RO, Carabello BA, Chatterjee K, et al. 2008 Focused update incorporated into the ACC/AHA 2006 guidelines for the management of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 1998 Guidelines for the Management of Patients With Valvular Heart Disease): endorsed by the Society of Cardiovascular Anesthesiologists, Society for Cardiovascular Angiography and Interventions, and Society of Thoracic Surgeons. Circulation. 2008;118(15):e523e661.
  7. Grines CL, Bonow RO, Casey DE, et al. Prevention of premature discontinuation of dual antiplatelet therapy in patients with coronary artery stents: a science advisory from the American Heart Association, American College of Cardiology, Society for Cardiovascular Angiography and Interventions, American College of Surgeons, and American Dental Association, with representation from the American College of Physicians. J Am Coll Cardiol. 2007;49(6):734739.
  8. Douketis JD, Spyropoulos AC, Spencer FA, et al. Perioperative management of antithrombotic therapy: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 Suppl):e326Se350S.
  9. Schulman S, AngerAS U, Bergqvist D, et al. Definition of major bleeding in clinical investigations of antihemostatic medicinal products in surgical patients. J Thromb Haemost. 2010;8(1):202204.
  10. Spyropoulos AC, Turpie AG, Dunn AS, et al. Clinical outcomes with unfractionated heparin or low‐molecular‐weight heparin as bridging therapy in patients on long‐term oral anticoagulants: the REGIMEN registry. J Thromb Haemost. 2006;4(6):12461252.
  11. Manchikanti L, Falco FJ, Benyamin RM, et al. Assessment of bleeding risk of interventional techniques: a best evidence synthesis of practice patterns and perioperative management of anticoagulant and antithrombotic therapy. Pain Physician. 2013;16(2 suppl):Se261Se318.
  12. Dunn AS, Turpie AG. Perioperative management of patients receiving oral anticoagulants: a systematic review. Arch Intern Med. 2003;163(8):901908.
  13. Salvati G, Punzi L, Pianon M, et al. Frequency of the bleeding risk in patients receiving warfarin submitted to arthrocentesis of the knee [in Italian]. Reumatismo. 2003;55(3):159163.
  14. Thumboo J, O'Duffy JD. A prospective study of the safety of joint and soft tissue aspirations and injections in patients taking warfarin sodium. Arthritis Rheum. 1998;41(4):736739.
  15. Ahmed I, Gertner E. Safety of arthrocentesis and joint injection in patients receiving anticoagulation at therapeutic levels. Am J Med. 2012;125(3):265269.
  16. Moen V, Dahlgren N, Irestedt L. Severe neurological complications after central neuraxial blockades in Sweden 1990–1999. Anesthesiology. 2004;101(4):950959.
  17. Green L, Machin SJ. Managing anticoagulated patients during neuraxial anaesthesia. Br J Haematol. 2010;149(2):195208.
  18. Stafford‐Smith M. Impaired haemostasis and regional anaesthesia. Can J Anaesth. 1996;43(5 pt 2):R129R141.
  19. Sinclair AJ, Carroll C, Davies B. Cauda equina syndrome following a lumbar puncture. J Clin Neurosci. 2009;16(5):714716.
  20. United States Food and Drug Safety Communication: updated recommendations to decrease risk of spinal column bleeding and paralysis in patients on low molecular weight heparins. Available at: http://www.fda.gov/Drugs/DrugSafety/ucm373595.htm. Accessed January 6, 2014.
  21. Davis JJ, Bankhead BR, Eckman EJ, Wallace A, Strunk J. Three‐times‐daily subcutaneous unfractionated heparin and neuraxial anesthesia: a retrospective review of 928 cases. Reg Anesth Pain Med. 2012;37(6):623626.
  22. Gogarten W, Vandermeulen E, Aken H, et al. Regional anaesthesia and antithrombotic agents: recommendations of the European Society of Anaesthesiology. Eur J Anaesthesiol. 2010;27(12):9991015.
  23. Eisai Inc. Fragmin (dalteparin sodium injection) full prescribing information. 2009. Available at: http://us.eisai.com/wps/wcm/connect/Eisai/Home/Our+Products/FRAGMIN. Accessed January 6, 2014
  24. Sanofi‐Aventis. Lovenox (enoxaparin sodium injection) full prescribing information. 2013. Available at: http://products.sanofi.us/lovenox/lovenox.html. Accessed January 6, 2014.
  25. LEO Pharmaceutical Products. Innohep (tinzaparin sodium injection) full prescribing information. 2008. Available at: http://www.accessdata.fda.gov/drugsatfda_docs/label/2008/020484s011lbl.pdf. Accessed January 6, 2014.
  26. Horlocker TT, Wedel DJ, Schroeder DR, et al. Preoperative antiplatelet therapy does not increase the risk of spinal hematoma associated with regional anesthesia. Anesth Analg. 1995;80(2):303309.
  27. Patel IJ, Davidson JC, Nikolic B, et al. Addendum of newer anticoagulants to the SIR consensus guideline. J Vasc Interv Radiol. 2013;24(5):641645.
  28. Pache I, Bilodeau M. Severe haemorrhage following abdominal paracentesis for ascites in patients with liver disease. Aliment Pharmacol Ther. 2005;21(5):525529.
  29. Mercaldi CJ, Lanes SF. Ultrasound guidance decreases complications and improves the cost of care among patients undergoing thoracentesis and paracentesis. Chest. 2013;143(2):532538.
  30. Runyon BA. Management of adult patients with ascites due to cirrhosis. Hepatology. 2004;39(3):841856.
  31. Tripodi A, Mannucci PM. The coagulopathy of chronic liver disease. N Engl J Med. 2011;365(2):147156.
  32. Doyle JJ, Hnatiuk OW, Torrington KG, Slade AR, Howard RS. Necessity of routine chest roentgenography after thoracentesis. Ann Intern Med. 1996;124(9):816820.
  33. Wrightson JM, Helm EJ, Rahman NM, Gleeson FV, Davies RJ. Pleural procedures and pleuroscopy. Respirology. 2009;14(6):796807.
  34. Patel PA, Ernst FR, Gunnarsson CL. Ultrasonography guidance reduces complications and costs associated with thoracentesis procedures. J Clin Ultrasound. 2012;40(3):135141.
  35. Duncan DR, Morgenthaler TI, Ryu JH, Daniels CE. Reducing iatrogenic risk in thoracentesis: establishing best practice via experiential training in a zero‐risk environment. Chest. 2009;135(5):13151320.
  36. Daniels CE, Ryu JH. Improving the safety of thoracentesis. Curr Opin Pulm Med. 2011;17(4):232236.
  37. Puchalski JT, Argento AC, Murphy TE, Araujo KL, Pisani MA. The safety of thoracentesis in patients with uncorrected bleeding risk. Ann Am Thorac Soc. 2013;10(4):336341.
  38. Hibbert RM, Atwell TD, Lekah A, et al. Safety of ultrasound‐guided thoracentesis in patients with abnormal preprocedural coagulation parameters. Chest. 2013;144(2):456463.
  39. Patel MD, Joshi SD. Abnormal preprocedural international normalized ratio and platelet counts are not associated with increased bleeding complications after ultrasound‐guided thoracentesis. AJR Am J Roentgenol. 2011;197(1):W164W168.
  40. McVay PA, Toy PT. Lack of increased bleeding after paracentesis and thoracentesis in patients with mild coagulation abnormalities. Transfusion. 1991;31(2):164171.
  41. Dammert P, Pratter M, Boujaoude Z. Safety of ultrasound‐guided small‐bore chest tube insertion in patients on clopidogrel. J Bronchology Interv Pulmonol. 2013;20(1):1620.
  42. Zalt MB, Bechara RI, Parks C, Berkowitz DM. Effect of routine clopidogrel use on bleeding complications after ultrasound‐guided thoracentesis. J Bronchology Interv Pulmonol. 2012;19(4):284287.
  43. McGee DC, Gould MK. Preventing complications of central venous catheterization. N Engl J Med. 2003;348(12):11231133.
  44. Ruesch S, Walder B, Tramer MR. Complications of central venous catheters: internal jugular versus subclavian access—a systematic review. Crit Care Med. 2002;30(2):454460.
  45. Theodoro D, Krauss M, Kollef M, Evanoff B. Risk factors for acute adverse events during ultrasound‐guided central venous cannulation in the emergency department. Acad Emerg Med. 2010;17(10):10551061.
  46. Kusminsky RE. Complications of central venous catheterization. J Am Coll Surg. 2007;204(4):681696.
  47. Wu SY, Ling Q, Cao LH, Wang J, Xu MX, Zeng WA. Real‐time two‐dimensional ultrasound guidance for central venous cannulation: a meta‐analysis. Anesthesiology. 2013;118(2):361375.
  48. Doerfler ME, Kaufman B, Goldenberg AS. Central venous catheter placement in patients with disorders of hemostasis. Chest. 1996;110(1):185188.
  49. DeLoughery TG, Liebler JM, Simonds V, Goodnight SH. Invasive line placement in critically ill patients: do hemostatic defects matter? Transfusion. 1996;36(9):827831.
  50. Kander T, Frigyesi A, Kjeldsen‐Kragh J, Karlsson H, Rolander F, Schott U. Bleeding complications after central line insertions: relevance of pre‐procedure coagulation tests and institutional transfusion policy. Acta Anaesthesiol Scand. 2013;57(5):573579.
  51. Weigand K, Encke J, Meyer FJ, et al. Low levels of prothrombin time (INR) and platelets do not increase the risk of significant bleeding when placing central venous catheters. Med Klin (Munich). 2009;104(5):331335.
  52. Della Vigna P, Monfardini L, Bonomo G, et al. Coagulation disorders in patients with cancer: nontunneled central venous catheter placement with US guidance—a single‐institution retrospective analysis. Radiology. 2009;253(1):249252.
  53. Tercan F, Ozkan U, Oguzkurt L. US‐guided placement of central vein catheters in patients with disorders of hemostasis. Eur J Radiol. 2008;65(2):253256.
  54. Carino GP, Tsapenko AV, Sweeney JD. Central line placement in patients with and without prophylactic plasma. J Crit Care. 2012;27(5):529.e529e513.
  55. Siegal DM, Garcia DA, Crowther MA. How I treat: target specific oral anticoagulant associated bleeding [published online ahead of print January 2, 2014]. Blood. doi: 10.1182/blood‐2013‐09‐529784.
  56. Douketis JD, Berger PB, Dunn AS, et al. The perioperative management of antithrombotic therapy: American College of Chest Physicians evidence‐based clinical practice guidelines (8th edition). Chest. 2008;133(6 suppl):299S339S.
  57. Kearon C, Hirsh J. Management of anticoagulation before and after elective surgery. N Engl J Med. 1997;336(21):15061511.
  58. Garcia DA, Regan S, Henault LE, et al. RIsk of thromboembolism with short‐term interruption of warfarin therapy. Arch Intern Med. 2008;168(1):6369.
  59. Healey JS, Eikelboom J, Douketis J, et al. Periprocedural bleeding and thromboembolic events with dabigatran compared with warfarin: results from the Randomized Evaluation of Long‐Term Anticoagulation Therapy (RE‐LY) randomized trial. Circulation. 2012;126(3):343348.
  60. Siegal D, Yudin J, Kaatz S, Douketis JD, Lim W, Spyropoulos AC. Periprocedural heparin bridging in patients receiving vitamin K antagonists: systematic review and meta‐analysis of bleeding and thromboembolic rates. Circulation. 2012;126(13):16301639.
  61. Gould MK, Garcia DA, Wren SM, et al. Prevention of VTE in nonorthopedic surgical patients: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 Suppl):e227S277S.
  62. McBane RD, Wysokinski WE, Daniels PR, et al. Periprocedural anticoagulation management of patients with venous thromboembolism. Arterioscler Thromb Vasc Biol. 2010;30(3):442448.
  63. Windecker S, Meier B. Late coronary stent thrombosis. Circulation. 2007;116(17):19521965.
  64. Werkum JW, Heestermans AA, Zomer AC, et al. Predictors of coronary stent thrombosis: the Dutch Stent Thrombosis Registry. J Am Coll Cardiol. 2009;53(16):13991409.
  65. Tafur AJ, McBane R, Wysokinski WE, et al. Predictors of major bleeding in peri‐procedural anticoagulation management. J Thromb Haemost. 2012;10(2):261267.
  66. Chassot PG, Delabays A, Spahn DR. Perioperative antiplatelet therapy: the case for continuing therapy in patients at risk of myocardial infarction. Br J Anaesth. 2007;99(3):316328.
  67. Ortel TL, Hasselblad V. Effectiveness of bridging anticoagulation for surgery (the BRIDGE Study). Available at: www.ClinicalTrials.gov. Identifier: NCT00786474. Accessed October 22, 2013.
  68. Kovacs MJ. A safety and effectiveness study of LMWH bridging therapy versus placebo bridging therapy for patients on long term warfarin and require temporary interruption of their warfarin (PERIOP2). Available at: www.ClinicalTrials.gov. Identifier: NCT00432796. Accessed October 20, 2013.
  69. Alshawabkeh LI, Prasad A, Lenkovsky F, et al. Outcomes of a preoperative “bridging” strategy with glycoprotein IIb/IIIa inhibitors to prevent perioperative stent thrombosis in patients with drug‐eluting stents who undergo surgery necessitating interruption of thienopyridine administration. EuroIntervention. 2013;9(2):204211.
  70. Rassi AN, Blackstone E, Militello MA, et al. Safety of “bridging” with eptifibatide for patients with coronary stents before cardiac and non‐cardiac surgery. Am J Cardiol. 2012;110(4):485490.
  71. Edmunds LH. Hemostatic problems in surgical patients. In: Colman RW HJ, Marder VJ, Clowes AW, George JN, ed. Hemostasis and Thrombosis. 4th ed. Philadelphia, PA: Lippincott Williams 2001:1033.
  72. Dzik WS. Reversal of drug‐induced anticoagulation: old solutions and new problems. Transfusion. 2012;52:45S55S.
  73. Larson BJ, Zumberg MS, Kitchens CS. A feasibility study of continuing dose‐reduced warfarin for invasive procedures in patients with high thromboembolic risk. Chest. 2005;127(3):922927.
  74. Marietta M, Bertesi M, Simoni L, et al. A simple and safe nomogram for the management of oral anticoagulation prior to minor surgery. Clin Lab Haematol. 2003;25(2):127130.
  75. Gulati G, Hevelow M, George M, Behling E, Siegel J. International normalized ratio versus plasma levels of coagulation factors in patients on vitamin K antagonist therapy. Arch Pathol Lab Med. 2011;135(4):490494.
  76. Garcia DA, Baglin TP, Weitz JI, Samama MM. Parenteral anticoagulants: antithrombotic therapy and prevention of thrombosis, 9th ed: American College Of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e24Se43S.
  77. Douketis JD, Woods K, Foster GA, Crowther MA. Bridging anticoagulation with low‐molecular‐weight heparin after interruption of warfarin therapy is associated with a residual anticoagulant effect prior to surgery. Thromb Haemost. 2005;94(3):528531.
  78. O'Donnell MJ, Kearon C, Johnson J, et al. Brief communication: Preoperative anticoagulant activity after bridging low‐molecular‐weight heparin for temporary interruption of warfarin. Ann Intern Med. 2007;146(3):184187.
  79. Horlocker TT. Regional anaesthesia in the patient receiving antithrombotic and antiplatelet therapy. Br J Anaesth. 2011;107(suppl 1):i96i106.
  80. Lim W, Dentali F, Eikelboom JW, Crowther MA. Meta‐analysis: low‐molecular‐weight heparin and bleeding in patients with severe renal insufficiency. Ann Intern Med. 2006;144(9):673684.
  81. Janssen Pharmaceuticals, Inc. Xarelto (rivaroxaban) full prescribing information. 2013. Available at: http://www.xareltohcp.com/sites/default/files/pdf/xarelto_0.pdf#zoom=100. Accessed October 1, 2013.
  82. Bristol Meyers Squibb, Inc. Eliquis (apixaban) full prescribing information. 2013. Available at: http://packageinserts.bms.com/pi/pi_eliquis.pdf. Accessed October 1, 2013.
  83. Boehringer Ingelheim Pharmaceuticals I. Pradaxa (dabigatran etexilate mesylate) full prescribing information. Available at: http://bidocs.boehringer‐ingelheim.com/BIWebAccess/ViewServlet.ser?docBase= renetnt11(2):245252.
  84. Tripodi A. The laboratory and the direct oral anticoagulants. Blood. 2013;121(20):40324035.
  85. Douxfils J, Mullier F, Loosen C, Chatelain C, Chatelain B, Dogne JM. Assessment of the impact of rivaroxaban on coagulation assays: laboratory recommendations for the monitoring of rivaroxaban and review of the literature. Thromb Res. 2012;130(6):956966.
  86. Eikelboom JW, Hirsh J, Spencer FA, Baglin TP, Weitz JI. Antiplatelet drugs: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e89S119S.
  87. Slichter SJ. Evidence‐based platelet transfusion guidelines. Hematology Am Soc Hematol Educ Program. 2007:172178.
  88. Grove EL, Hossain R, Storey RF. Platelet function testing and prediction of procedural bleeding risk. Thromb Haemost. 2013;109(5):817824.
  89. Darvish‐Kazem S, Gandhi M, Marcucci M, Douketis JD. Perioperative management of antiplatelet therapy in patients with a coronary stent who need non‐cardiac surgery: a systematic review of clinical practice guidelines. Chest. 2013;144(6):18481856.
  90. Eli Lilly Pharmaceuticals, Inc. Effient (prasugrel) full prescribing information. 2012. Available at: http://pi.lilly.com/us/effient.pdf. Accessed October 1, 2013.
  91. Fitchett D, Mazer CD, Eikelboom J, Verma S. Antiplatelet therapy and cardiac surgery: review of recent evidence and clinical implications. Can J Cardiol. 2013;29(9):10421047.
  92. AstraZeneca. Brilinta (ticagrelor) full prescribing information. 2013. Available at: http://www1.astrazeneca‐us.com/pi/brilinta.pdf. Accessed October 1, 2013.
  93. Ferraris VA, Saha SP, Oestreich JH, et al. 2012 update to the Society of Thoracic Surgeons guideline on use of antiplatelet drugs in patients having cardiac and noncardiac operations. Ann Thorac Surg. 2012;94(5):17611781.
  94. Spyropoulos AC, Douketis JD. How I treat anticoagulated patients undergoing an elective procedure or surgery. Blood. 2012;120(15):29542962.
  95. Garcia DA, Baglin TP, Weitz JI, Samama MM, American College of Chest Physicians. Parenteral anticoagulants: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e24Se43S.
References
  1. Dressler DD, Pistoria MJ, Budnitz TL, McKean SC, Amin AN. Core competencies in hospital medicine: development and methodology. J Hosp Med. 2006;1(suppl 1):4856.
  2. Thakkar R, Wright SM, Alguire P, Wigton RS, Boonyasai RT. Procedures performed by hospitalist and non‐hospitalist general internists. J Gen Int Med. 2010;25(5):448452.
  3. Horlocker TT, Wedel DJ, Rowlingson JC, et al. Regional anesthesia in the patient receiving antithrombotic or thrombolytic therapy: American Society of Regional Anesthesia and Pain Medicine evidence‐based guidelines (Third Edition). Reg Anesth Pain Med. 2010;35(1):64101.
  4. ASGE Standards of Practice Committee, Anderson MA, Ben‐Menachem T, Gan SI, et al. Management of antithrombotic agents for endoscopic procedures. Gastrointest Endosc. 2009;70(6):10601070.
  5. Patel IJ, Davidson JC, Nikolic B, et al. Consensus guidelines for periprocedural management of coagulation status and hemostasis risk in percutaneous image‐guided interventions. J Vasc Interv Radiol. 2012;23(6):727736.
  6. Bonow RO, Carabello BA, Chatterjee K, et al. 2008 Focused update incorporated into the ACC/AHA 2006 guidelines for the management of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 1998 Guidelines for the Management of Patients With Valvular Heart Disease): endorsed by the Society of Cardiovascular Anesthesiologists, Society for Cardiovascular Angiography and Interventions, and Society of Thoracic Surgeons. Circulation. 2008;118(15):e523e661.
  7. Grines CL, Bonow RO, Casey DE, et al. Prevention of premature discontinuation of dual antiplatelet therapy in patients with coronary artery stents: a science advisory from the American Heart Association, American College of Cardiology, Society for Cardiovascular Angiography and Interventions, American College of Surgeons, and American Dental Association, with representation from the American College of Physicians. J Am Coll Cardiol. 2007;49(6):734739.
  8. Douketis JD, Spyropoulos AC, Spencer FA, et al. Perioperative management of antithrombotic therapy: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 Suppl):e326Se350S.
  9. Schulman S, AngerAS U, Bergqvist D, et al. Definition of major bleeding in clinical investigations of antihemostatic medicinal products in surgical patients. J Thromb Haemost. 2010;8(1):202204.
  10. Spyropoulos AC, Turpie AG, Dunn AS, et al. Clinical outcomes with unfractionated heparin or low‐molecular‐weight heparin as bridging therapy in patients on long‐term oral anticoagulants: the REGIMEN registry. J Thromb Haemost. 2006;4(6):12461252.
  11. Manchikanti L, Falco FJ, Benyamin RM, et al. Assessment of bleeding risk of interventional techniques: a best evidence synthesis of practice patterns and perioperative management of anticoagulant and antithrombotic therapy. Pain Physician. 2013;16(2 suppl):Se261Se318.
  12. Dunn AS, Turpie AG. Perioperative management of patients receiving oral anticoagulants: a systematic review. Arch Intern Med. 2003;163(8):901908.
  13. Salvati G, Punzi L, Pianon M, et al. Frequency of the bleeding risk in patients receiving warfarin submitted to arthrocentesis of the knee [in Italian]. Reumatismo. 2003;55(3):159163.
  14. Thumboo J, O'Duffy JD. A prospective study of the safety of joint and soft tissue aspirations and injections in patients taking warfarin sodium. Arthritis Rheum. 1998;41(4):736739.
  15. Ahmed I, Gertner E. Safety of arthrocentesis and joint injection in patients receiving anticoagulation at therapeutic levels. Am J Med. 2012;125(3):265269.
  16. Moen V, Dahlgren N, Irestedt L. Severe neurological complications after central neuraxial blockades in Sweden 1990–1999. Anesthesiology. 2004;101(4):950959.
  17. Green L, Machin SJ. Managing anticoagulated patients during neuraxial anaesthesia. Br J Haematol. 2010;149(2):195208.
  18. Stafford‐Smith M. Impaired haemostasis and regional anaesthesia. Can J Anaesth. 1996;43(5 pt 2):R129R141.
  19. Sinclair AJ, Carroll C, Davies B. Cauda equina syndrome following a lumbar puncture. J Clin Neurosci. 2009;16(5):714716.
  20. United States Food and Drug Safety Communication: updated recommendations to decrease risk of spinal column bleeding and paralysis in patients on low molecular weight heparins. Available at: http://www.fda.gov/Drugs/DrugSafety/ucm373595.htm. Accessed January 6, 2014.
  21. Davis JJ, Bankhead BR, Eckman EJ, Wallace A, Strunk J. Three‐times‐daily subcutaneous unfractionated heparin and neuraxial anesthesia: a retrospective review of 928 cases. Reg Anesth Pain Med. 2012;37(6):623626.
  22. Gogarten W, Vandermeulen E, Aken H, et al. Regional anaesthesia and antithrombotic agents: recommendations of the European Society of Anaesthesiology. Eur J Anaesthesiol. 2010;27(12):9991015.
  23. Eisai Inc. Fragmin (dalteparin sodium injection) full prescribing information. 2009. Available at: http://us.eisai.com/wps/wcm/connect/Eisai/Home/Our+Products/FRAGMIN. Accessed January 6, 2014
  24. Sanofi‐Aventis. Lovenox (enoxaparin sodium injection) full prescribing information. 2013. Available at: http://products.sanofi.us/lovenox/lovenox.html. Accessed January 6, 2014.
  25. LEO Pharmaceutical Products. Innohep (tinzaparin sodium injection) full prescribing information. 2008. Available at: http://www.accessdata.fda.gov/drugsatfda_docs/label/2008/020484s011lbl.pdf. Accessed January 6, 2014.
  26. Horlocker TT, Wedel DJ, Schroeder DR, et al. Preoperative antiplatelet therapy does not increase the risk of spinal hematoma associated with regional anesthesia. Anesth Analg. 1995;80(2):303309.
  27. Patel IJ, Davidson JC, Nikolic B, et al. Addendum of newer anticoagulants to the SIR consensus guideline. J Vasc Interv Radiol. 2013;24(5):641645.
  28. Pache I, Bilodeau M. Severe haemorrhage following abdominal paracentesis for ascites in patients with liver disease. Aliment Pharmacol Ther. 2005;21(5):525529.
  29. Mercaldi CJ, Lanes SF. Ultrasound guidance decreases complications and improves the cost of care among patients undergoing thoracentesis and paracentesis. Chest. 2013;143(2):532538.
  30. Runyon BA. Management of adult patients with ascites due to cirrhosis. Hepatology. 2004;39(3):841856.
  31. Tripodi A, Mannucci PM. The coagulopathy of chronic liver disease. N Engl J Med. 2011;365(2):147156.
  32. Doyle JJ, Hnatiuk OW, Torrington KG, Slade AR, Howard RS. Necessity of routine chest roentgenography after thoracentesis. Ann Intern Med. 1996;124(9):816820.
  33. Wrightson JM, Helm EJ, Rahman NM, Gleeson FV, Davies RJ. Pleural procedures and pleuroscopy. Respirology. 2009;14(6):796807.
  34. Patel PA, Ernst FR, Gunnarsson CL. Ultrasonography guidance reduces complications and costs associated with thoracentesis procedures. J Clin Ultrasound. 2012;40(3):135141.
  35. Duncan DR, Morgenthaler TI, Ryu JH, Daniels CE. Reducing iatrogenic risk in thoracentesis: establishing best practice via experiential training in a zero‐risk environment. Chest. 2009;135(5):13151320.
  36. Daniels CE, Ryu JH. Improving the safety of thoracentesis. Curr Opin Pulm Med. 2011;17(4):232236.
  37. Puchalski JT, Argento AC, Murphy TE, Araujo KL, Pisani MA. The safety of thoracentesis in patients with uncorrected bleeding risk. Ann Am Thorac Soc. 2013;10(4):336341.
  38. Hibbert RM, Atwell TD, Lekah A, et al. Safety of ultrasound‐guided thoracentesis in patients with abnormal preprocedural coagulation parameters. Chest. 2013;144(2):456463.
  39. Patel MD, Joshi SD. Abnormal preprocedural international normalized ratio and platelet counts are not associated with increased bleeding complications after ultrasound‐guided thoracentesis. AJR Am J Roentgenol. 2011;197(1):W164W168.
  40. McVay PA, Toy PT. Lack of increased bleeding after paracentesis and thoracentesis in patients with mild coagulation abnormalities. Transfusion. 1991;31(2):164171.
  41. Dammert P, Pratter M, Boujaoude Z. Safety of ultrasound‐guided small‐bore chest tube insertion in patients on clopidogrel. J Bronchology Interv Pulmonol. 2013;20(1):1620.
  42. Zalt MB, Bechara RI, Parks C, Berkowitz DM. Effect of routine clopidogrel use on bleeding complications after ultrasound‐guided thoracentesis. J Bronchology Interv Pulmonol. 2012;19(4):284287.
  43. McGee DC, Gould MK. Preventing complications of central venous catheterization. N Engl J Med. 2003;348(12):11231133.
  44. Ruesch S, Walder B, Tramer MR. Complications of central venous catheters: internal jugular versus subclavian access—a systematic review. Crit Care Med. 2002;30(2):454460.
  45. Theodoro D, Krauss M, Kollef M, Evanoff B. Risk factors for acute adverse events during ultrasound‐guided central venous cannulation in the emergency department. Acad Emerg Med. 2010;17(10):10551061.
  46. Kusminsky RE. Complications of central venous catheterization. J Am Coll Surg. 2007;204(4):681696.
  47. Wu SY, Ling Q, Cao LH, Wang J, Xu MX, Zeng WA. Real‐time two‐dimensional ultrasound guidance for central venous cannulation: a meta‐analysis. Anesthesiology. 2013;118(2):361375.
  48. Doerfler ME, Kaufman B, Goldenberg AS. Central venous catheter placement in patients with disorders of hemostasis. Chest. 1996;110(1):185188.
  49. DeLoughery TG, Liebler JM, Simonds V, Goodnight SH. Invasive line placement in critically ill patients: do hemostatic defects matter? Transfusion. 1996;36(9):827831.
  50. Kander T, Frigyesi A, Kjeldsen‐Kragh J, Karlsson H, Rolander F, Schott U. Bleeding complications after central line insertions: relevance of pre‐procedure coagulation tests and institutional transfusion policy. Acta Anaesthesiol Scand. 2013;57(5):573579.
  51. Weigand K, Encke J, Meyer FJ, et al. Low levels of prothrombin time (INR) and platelets do not increase the risk of significant bleeding when placing central venous catheters. Med Klin (Munich). 2009;104(5):331335.
  52. Della Vigna P, Monfardini L, Bonomo G, et al. Coagulation disorders in patients with cancer: nontunneled central venous catheter placement with US guidance—a single‐institution retrospective analysis. Radiology. 2009;253(1):249252.
  53. Tercan F, Ozkan U, Oguzkurt L. US‐guided placement of central vein catheters in patients with disorders of hemostasis. Eur J Radiol. 2008;65(2):253256.
  54. Carino GP, Tsapenko AV, Sweeney JD. Central line placement in patients with and without prophylactic plasma. J Crit Care. 2012;27(5):529.e529e513.
  55. Siegal DM, Garcia DA, Crowther MA. How I treat: target specific oral anticoagulant associated bleeding [published online ahead of print January 2, 2014]. Blood. doi: 10.1182/blood‐2013‐09‐529784.
  56. Douketis JD, Berger PB, Dunn AS, et al. The perioperative management of antithrombotic therapy: American College of Chest Physicians evidence‐based clinical practice guidelines (8th edition). Chest. 2008;133(6 suppl):299S339S.
  57. Kearon C, Hirsh J. Management of anticoagulation before and after elective surgery. N Engl J Med. 1997;336(21):15061511.
  58. Garcia DA, Regan S, Henault LE, et al. RIsk of thromboembolism with short‐term interruption of warfarin therapy. Arch Intern Med. 2008;168(1):6369.
  59. Healey JS, Eikelboom J, Douketis J, et al. Periprocedural bleeding and thromboembolic events with dabigatran compared with warfarin: results from the Randomized Evaluation of Long‐Term Anticoagulation Therapy (RE‐LY) randomized trial. Circulation. 2012;126(3):343348.
  60. Siegal D, Yudin J, Kaatz S, Douketis JD, Lim W, Spyropoulos AC. Periprocedural heparin bridging in patients receiving vitamin K antagonists: systematic review and meta‐analysis of bleeding and thromboembolic rates. Circulation. 2012;126(13):16301639.
  61. Gould MK, Garcia DA, Wren SM, et al. Prevention of VTE in nonorthopedic surgical patients: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 Suppl):e227S277S.
  62. McBane RD, Wysokinski WE, Daniels PR, et al. Periprocedural anticoagulation management of patients with venous thromboembolism. Arterioscler Thromb Vasc Biol. 2010;30(3):442448.
  63. Windecker S, Meier B. Late coronary stent thrombosis. Circulation. 2007;116(17):19521965.
  64. Werkum JW, Heestermans AA, Zomer AC, et al. Predictors of coronary stent thrombosis: the Dutch Stent Thrombosis Registry. J Am Coll Cardiol. 2009;53(16):13991409.
  65. Tafur AJ, McBane R, Wysokinski WE, et al. Predictors of major bleeding in peri‐procedural anticoagulation management. J Thromb Haemost. 2012;10(2):261267.
  66. Chassot PG, Delabays A, Spahn DR. Perioperative antiplatelet therapy: the case for continuing therapy in patients at risk of myocardial infarction. Br J Anaesth. 2007;99(3):316328.
  67. Ortel TL, Hasselblad V. Effectiveness of bridging anticoagulation for surgery (the BRIDGE Study). Available at: www.ClinicalTrials.gov. Identifier: NCT00786474. Accessed October 22, 2013.
  68. Kovacs MJ. A safety and effectiveness study of LMWH bridging therapy versus placebo bridging therapy for patients on long term warfarin and require temporary interruption of their warfarin (PERIOP2). Available at: www.ClinicalTrials.gov. Identifier: NCT00432796. Accessed October 20, 2013.
  69. Alshawabkeh LI, Prasad A, Lenkovsky F, et al. Outcomes of a preoperative “bridging” strategy with glycoprotein IIb/IIIa inhibitors to prevent perioperative stent thrombosis in patients with drug‐eluting stents who undergo surgery necessitating interruption of thienopyridine administration. EuroIntervention. 2013;9(2):204211.
  70. Rassi AN, Blackstone E, Militello MA, et al. Safety of “bridging” with eptifibatide for patients with coronary stents before cardiac and non‐cardiac surgery. Am J Cardiol. 2012;110(4):485490.
  71. Edmunds LH. Hemostatic problems in surgical patients. In: Colman RW HJ, Marder VJ, Clowes AW, George JN, ed. Hemostasis and Thrombosis. 4th ed. Philadelphia, PA: Lippincott Williams 2001:1033.
  72. Dzik WS. Reversal of drug‐induced anticoagulation: old solutions and new problems. Transfusion. 2012;52:45S55S.
  73. Larson BJ, Zumberg MS, Kitchens CS. A feasibility study of continuing dose‐reduced warfarin for invasive procedures in patients with high thromboembolic risk. Chest. 2005;127(3):922927.
  74. Marietta M, Bertesi M, Simoni L, et al. A simple and safe nomogram for the management of oral anticoagulation prior to minor surgery. Clin Lab Haematol. 2003;25(2):127130.
  75. Gulati G, Hevelow M, George M, Behling E, Siegel J. International normalized ratio versus plasma levels of coagulation factors in patients on vitamin K antagonist therapy. Arch Pathol Lab Med. 2011;135(4):490494.
  76. Garcia DA, Baglin TP, Weitz JI, Samama MM. Parenteral anticoagulants: antithrombotic therapy and prevention of thrombosis, 9th ed: American College Of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e24Se43S.
  77. Douketis JD, Woods K, Foster GA, Crowther MA. Bridging anticoagulation with low‐molecular‐weight heparin after interruption of warfarin therapy is associated with a residual anticoagulant effect prior to surgery. Thromb Haemost. 2005;94(3):528531.
  78. O'Donnell MJ, Kearon C, Johnson J, et al. Brief communication: Preoperative anticoagulant activity after bridging low‐molecular‐weight heparin for temporary interruption of warfarin. Ann Intern Med. 2007;146(3):184187.
  79. Horlocker TT. Regional anaesthesia in the patient receiving antithrombotic and antiplatelet therapy. Br J Anaesth. 2011;107(suppl 1):i96i106.
  80. Lim W, Dentali F, Eikelboom JW, Crowther MA. Meta‐analysis: low‐molecular‐weight heparin and bleeding in patients with severe renal insufficiency. Ann Intern Med. 2006;144(9):673684.
  81. Janssen Pharmaceuticals, Inc. Xarelto (rivaroxaban) full prescribing information. 2013. Available at: http://www.xareltohcp.com/sites/default/files/pdf/xarelto_0.pdf#zoom=100. Accessed October 1, 2013.
  82. Bristol Meyers Squibb, Inc. Eliquis (apixaban) full prescribing information. 2013. Available at: http://packageinserts.bms.com/pi/pi_eliquis.pdf. Accessed October 1, 2013.
  83. Boehringer Ingelheim Pharmaceuticals I. Pradaxa (dabigatran etexilate mesylate) full prescribing information. Available at: http://bidocs.boehringer‐ingelheim.com/BIWebAccess/ViewServlet.ser?docBase= renetnt11(2):245252.
  84. Tripodi A. The laboratory and the direct oral anticoagulants. Blood. 2013;121(20):40324035.
  85. Douxfils J, Mullier F, Loosen C, Chatelain C, Chatelain B, Dogne JM. Assessment of the impact of rivaroxaban on coagulation assays: laboratory recommendations for the monitoring of rivaroxaban and review of the literature. Thromb Res. 2012;130(6):956966.
  86. Eikelboom JW, Hirsh J, Spencer FA, Baglin TP, Weitz JI. Antiplatelet drugs: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e89S119S.
  87. Slichter SJ. Evidence‐based platelet transfusion guidelines. Hematology Am Soc Hematol Educ Program. 2007:172178.
  88. Grove EL, Hossain R, Storey RF. Platelet function testing and prediction of procedural bleeding risk. Thromb Haemost. 2013;109(5):817824.
  89. Darvish‐Kazem S, Gandhi M, Marcucci M, Douketis JD. Perioperative management of antiplatelet therapy in patients with a coronary stent who need non‐cardiac surgery: a systematic review of clinical practice guidelines. Chest. 2013;144(6):18481856.
  90. Eli Lilly Pharmaceuticals, Inc. Effient (prasugrel) full prescribing information. 2012. Available at: http://pi.lilly.com/us/effient.pdf. Accessed October 1, 2013.
  91. Fitchett D, Mazer CD, Eikelboom J, Verma S. Antiplatelet therapy and cardiac surgery: review of recent evidence and clinical implications. Can J Cardiol. 2013;29(9):10421047.
  92. AstraZeneca. Brilinta (ticagrelor) full prescribing information. 2013. Available at: http://www1.astrazeneca‐us.com/pi/brilinta.pdf. Accessed October 1, 2013.
  93. Ferraris VA, Saha SP, Oestreich JH, et al. 2012 update to the Society of Thoracic Surgeons guideline on use of antiplatelet drugs in patients having cardiac and noncardiac operations. Ann Thorac Surg. 2012;94(5):17611781.
  94. Spyropoulos AC, Douketis JD. How I treat anticoagulated patients undergoing an elective procedure or surgery. Blood. 2012;120(15):29542962.
  95. Garcia DA, Baglin TP, Weitz JI, Samama MM, American College of Chest Physicians. Parenteral anticoagulants: antithrombotic therapy and prevention of thrombosis, 9th ed: American College of Chest Physicians evidence‐based clinical practice guidelines. Chest. 2012;141(2 suppl):e24Se43S.
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Journal of Hospital Medicine - 9(5)
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Journal of Hospital Medicine - 9(5)
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337-346
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Periprocedural management of antithrombotic therapy in hospitalized patients
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Periprocedural management of antithrombotic therapy in hospitalized patients
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Address for correspondence and reprint requests: David Feinbloom, MD, Section of Hospital Medicine, Division of General Medicine and Primary Care, Department of Medicine, Beth Israel Deaconess Medical Center, Harvard Medical School, Boston, MA 02215; Telephone: 617‐694‐5220; Fax: 617‐632‐0215; E‐mail: dfeinbloom@bidmc.harvard.edu
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