How to sustain a quality improvement effort

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Thu, 03/28/2019 - 14:59

 

In the final of a three-part series about developing and implementing a quality improvement initiative, Dr. Bernstein and his colleagues outline how such a program can be sustained and cemented into a gastroenterology practice. This mini-series has focused on community practices and presented a road map for quality improvement through descriptions of clinical vignettes – specifically focused on improving adenoma detection rates. In multiple other articles within the Toolbox series, we have described how gastroenterologists can measure and improve one of our most important outcome measures – the adenoma detection rate for screening colonoscopy. We all are aware of the Hawthorne effect (that is, observer effect) in which people modify their behavior in response to being measured or observed. The key to sustained quality improvement is to change fundamental practices once the flush of initial success fades.
 

John I. Allen, MD, MBA, AGAF

Editor in Chief

Series review

In this series, you are a community-based urban general gastroenterologist asked by hospital administration to improve your current group adenoma detection rate (ADR) of 19% to the established target of 25% among each individual endoscopist within the group during a 12-month period.

The team has implemented standardized endoscopist report cards during the past 9 months. At present, ADR has been more than 25% for all practitioners for 4 consecutive months. The quality improvement team meets to determine how to sustain the gains long term.

Sustainability of improved outcomes has been defined as: “When new ways of working and improved outcomes become the norm.”1 This incorporates a number of important concepts. “New ways of working” means that a change has been made in the way care has been provided. This includes interventions such as a new policy, implementation of a checklist, or a new clinical pathway. “Improved outcomes” implies that the result of the intervention has been measured and has demonstrated an improvement. “Become the norm” means that this change has now become a part of standard work and does not need ongoing support to continue.

Although a great deal of literature currently exists that focuses on initiation and implementation of quality improvement (QI) activities, much less has been written on sustaining efforts once the goal has been achieved. A number of reasons have been proposed for this, including stability being typically regarded as less interesting, as well as the research requiring much longer time frames for study.2 However, there is important evidence that suggests that up to 70% of long-term changes in health care organizations ultimately fail.3 This indicates a pressing need for effective strategies to sustain improved outcomes.

Challenges

A number of challenges face the sustainability phase of an intervention.2 First, the initial enthusiasm for a novel intervention wanes after time, often limiting long-term compliance if it has not become part of standard work. Second, the local or national support for a project may have changed as strategic priorities shift. This can result in a loss of leadership support and/or resources. Third, most institutions value novel ideas over a steady state, and focusing on the next initiative offers more career value for managers as compared with maintaining current practices. Finally, it is common for groups to declare victory too soon. This is defined as celebrating the first performance improvement as the final goal instead of it being the first step to long-term success.

Determining readiness for sustainability

The first step in determining readiness for sustaining an improvement is to determine whether there has been an actual improvement to sustain. This means both completing the plan-do-study-act cycles and establishing a true steady state. In addition, it needs to be demonstrated that a sustained change has occurred. The second article in this series addresses these steps in detail.4

The National Health Service (United Kingdom) Improvement Leaders’ Guide to Sustainability and Spread identifies four sets of questions to ask when determining whether a project can enter the sustainability phase.3

1. Is the (intervention) near the final stage of development? If there were room for further changes, would these completely alter the way the solution has been introduced?

2. Are the measurements demonstrating real improvement?

3. Who cares about this improvement? Is the solution representative of the wider views of those involved?

4. What policy or technological changes may render this solution redundant? When might this happen?

Once the answers to these questions have been determined and it is believed that a steady state has been achieved, it is time to move on to sustaining the intervention. Article no. 2 in our series outlines how to know whether an improvement has occurred. Although there is no single metric that can determine a project is in a steady state, it is generally believed that four or five cycles with consistent improvement and without special cause variation, along with an intervention that has been fully established, typically represent a steady state.

ACTION PLAN: For the ADR example, the answers to the questions are as follows:

 

 

1. The intervention was developed and finalized through iterative design among the QI team.

2. Performance has been consistently above target among all endoscopists for 4 consecutive months.

3. ADR is an important quality metric to individual endoscopists as well as hospital leadership. Moreover, because there are increasing models tying reimbursement to funding that are based on adherence to quality indicators, ADR will become more important.

4. If hospitals become mandated to provide scorecard data, the intervention may become redundant. However, the measurement and implications of the data still may be relevant to ongoing QI activities.

Interventions supporting sustainability

Sustainability planning is ideally started at the initiation phase of the project. When choosing a target for change, consideration of organizational factors such as strategic priorities, staff engagement, and leadership support are integral to long-term success. Factors influencing the type of intervention developed should include available funding (both long term and short term), existing information technology (IT) resources, and the ability to incorporate into existing workflow. Considering these factors from the outset will help improve a project’s long-term viability.

A number of toolkits have been produced to guide QI teams through the sustainability process. The National Health Service Institute for Innovation and Improvement has produced a comprehensive guide to sustainability.4 The guide provides advice on how to identify opportunities to increase the likelihood of sustainability for your initiative. It is accompanied by a model that can be used to predict success by dividing the factors influencing sustainability into three groups: staff, process, and organization. Each of these has a number of subcategories, and relative significance is attributed to each, with staff factors (clinical leadership engagement, senior leadership engagement, staff involvement in the change, and staff attitudes toward the change) holding the highest weighting. On the basis of the results of the model, the QI team can identify both the likelihood of success as well as opportunities for improvement.

Visual aids are another intervention that promotes sustainability. Visual cues such as posters, buttons, and magnets act as easy reminders for front-line staff. Creating a storyboard at the beginning of the project allows stakeholders to have a broad perspective on both the intervention and sustainability phases.5 Ongoing auditing and reporting of results also encourage long-term compliance. This can take the form of posting results of the intervention in the department on a regular basis as well as reports to senior administration. Regular check-ins with all stakeholders are also encouraged. This can be at a monthly staff meeting or a brief “improvement huddle” on a standing basis.

Factors influencing success

Any discussion of QI work must consider context. An understanding of the system one is working within will allow for optimization of system strengths and avoidance of pitfalls because of weaknesses. A lack of attention to context can lead to an unsuccessful project. This could be due to choosing a focus that is not in line with hospital priorities, a project that is asking staff to take on additional tasks without removing others, or developing a solution that requires funding or IT infrastructure that is not readily available.

Any organization has a number of different settings that need to be considered simultaneously. This is most simply divided into microsystem, mesosystem, and macrosystem. Microsystem is defined as the combination of a small team of people who work together on a regular basis. The mesosystem focuses on the integrated care needs of a particular group or population with the same diseases or conditions and provides support for individual microsystems. The macrosystem forms the infrastructure of the larger organization, providing the systems and governance that define the system.6 In our example, the microsystem is the endoscopy unit, including physicians, nurses, administrative support, and managers. The mesosystem is composed of the endoscopy unit in addition to the Departments of Gastroenterology and Surgery, the hospital IT team, and the Pathology Department. The macrosystem is the hospital, including senior leadership and administration. Another way of thinking about this is the microsystem is the environment most easily influenced by the individual provider, whereas the macrosystem includes the organizational-level factors that need to be taken into consideration when designing an intervention.

A great number of factors have been proposed to influence sustainability. National Health Service Scotland performed a literature review and met with subject matter experts to determine key factors that require consideration when engaging in activities to sustain and spread QI activities. They produced a guide that focused on 10 factors thought to have the greatest influence.6 Although a review of all 10 factors is beyond the scope of this review, we will highlight key ones to consider.

 

 

Innovation

The nature of the change greatly influences its likelihood of being sustained. In addition, one must consider the process of the intervention as well as those who will be impacted by the change. Core qualities that predispose to success include the following:7

1. Clear advantage compared with current ways

2. Compatibility/integration with current systems and values

3. Simplicity of the change and its implementation

4. Ease of testing

5. Observability of the change and its impact

This list highlights the point that the plan to sustain an intervention needs to start at the design phase and not once the change has been proven successful. Support among users also influences long-term success. Early adopters are those who embrace the intervention or change. Identifying the early adopters and using their support for positive publicity and momentum are integral in any sustainability effort.

ACTION PLAN: In our example, components of the intervention that would predispose to sustainability include choosing an outcome that is aligned with the hospital’s strategic focus (for example, cancer screening and prevention). ADR is already a measurable outcome at the hospital, which facilitates dissemination of results. Alternatively, some of the resistance to change may be due to the increased work to compile and distribute the scorecards monthly.

Organizational culture

Culture has been most simply defined as “the way we do things around here”.7 The approach of an organization toward QI will clearly impact its long-term viability. On a macrosystem level, interventions should ideally fit within strategic goals and priorities of organizations to garner maximum support. When promoting the intervention, it may be appropriate to focus on the benefits to the individual group (that is, cost savings to senior administration, time saved to front-line staff). Studies have shown that teams that demonstrate a strong teamwork ethic, have a positive attitude toward the intervention, and where all members know and understand their role on the team were more likely to have sustained success.8 In addition, engagement of all key stakeholders early in the process has been correlated with improved long-term outcomes. In a microsystem level, providers can choose to implement the intervention among a well-established team that works well together, ideally where there is a history or prior QI work.

Factors that may make sustaining a QI effort more challenging include interventions that increase time or costs to the organization. Many healthcare organizations may have specific targets set out from their regulatory body. If the intervention lowers the result of one of the targeted outcomes (or does not address those targets at all), it may be met with increased resistance within a system. In cases like this it is integral to use data to demonstrate to senior leadership why this still has tangible benefit to the organization.

ACTION PLAN: In our example, culture can promote sustainability on a microsystem level through reinforcing local success stories. This can be through posting of visual aids in the unit such as posters that display performance or progress boards that chart the status of the intervention. In addition, QI projects can be a regular agenda item at unit meetings, reinforcing their importance to team members.

Leadership

One key component of organizational culture is the influence of leadership. An effective leader will have both technical QI skills and strong interpersonal skills.7 Teams where all members feel comfortable making suggestions or voicing concerns are far more likely to succeed, and it is incumbent on leadership to create this environment. This concept is often termed psychological safety and has been directly linked to the inclusiveness of the leader. Team members with psychological safety are more likely to feel like active participants in the process, and this improves their long-term engagement.7,8 In addition, effective leaders create accountability systems to ensure gains are maintained. These may include regular performance reviews, reminders about the intervention, and assigning responsibility to senior level team members. Finally, celebration of accomplishments reinforces the positive impact of the time and energy invested by members of the team.9 The concept of distributed leadership is another key concept. This acknowledges that for any one intervention, there are a number of formal and informal leadership roles, and these can be filled by a number of different individuals.7

ACTION PLAN: For our ADR example, sustainability can be promoted through effective leadership. On a microsystem level, one option is the implementation of a weekly Improvement Huddle. This is a 10- to 15-minute meeting within the microsystem that is designed to review current performance and anticipate problems. All team members are encouraged to voice any concerns. On the macrosystem level, quarterly reports to senior administration and presentation of process and results at Grand Rounds may contribute to this goal.

 

 

Change management

Change management looks at how an organization approaches the new ways of working. This can be on both a social level and a technical level (often termed Organizational Infrastructure). Creating interventions that integrate with existing systems (data collection, workflow) is ideal for sustainability because it can serve to reinforce the change as standard work. In instances where the change does not immediately integrate, organizations can support change by demonstrating flexibility. This includes modification of existing technology to measure the desired outcome, development of new protocols to integrate the modified workflow, or changing job definitions of team members to demonstrate that the intervention is now considered part of daily responsibilities. Ongoing feedback also reinforces maintenance of performance. This can be through performance reviews for staff members as well as providing data to the appropriate audiences to demonstrate sustained gains.7,9

ACTION PLAN: For the ADR example, change management can contribute to sustainability through creation of a sustainable data reporting system that integrates current workflow. This will allow ongoing measurement of key metrics and is integral for long-term viability.

Summary

In this final article of a three-part series directed toward gastroenterologists interested in local QI endeavors, we selectively reviewed concepts surrounding sustainability of QI endeavors. This included determining readiness and understanding the factors that influence long-term success on both a macrosystem and microsystem level. Factors under the direct control of the individual practitioner were highlighted to give examples of specific strategies for successful sustainability.

References

1. Thomas, S., Zahn, D. Sustaining improved outcomes: a toolkit. Available at: http://nyshealthfoundation.org/resources-and-reports/resource/sustaining-improved-outcomes-a-toolkit.

2. Buchanan, D., Fitzgerald, L., Ketley, D., et al. No going back: a review of the literature on sustaining organizational change. Int. J Manag Rev. 2005;7:189-205.

3. Sustainability: model and guide. National Health Service Institute for Innovation and Improvement, Leeds, U.K.; 2007.

4. Improvement leaders’ guide to sustainability and spread. NHS Modernisation Agency. Ipswich, England: Ancient House Printing Group; 2002.

5. Nelson, E.C., Batalden, P.B., Godfrey, M.M. Quality by design: a clinical microsystems approach. Jossey-Bass, San Francisco, Calif; 2007.

6. Available at: http://www.ashpfoundation.org/lean.

7. NHS Scotland Quality Improvement Hub. The spread and sustainability of quality improvement in healthcare. 2014. Available at: http://www.qihub.scot.nhs.uk/knowledge-centre/quality-improvement-topics/spread-and-sustainability.aspx.

8. Healthcare Improvement Scotland. Quality improvement: sustainable in any organizational culture? 2013. Available at: http://www.healthcareimprovementscotland.org/previous_resources/benchmarking_report/quality_improvement_report.aspx.

9. 5 Million Lives Campaign. Getting started kit: rapid response teams. Institute for Healthcare Improvement, Cambridge, MA; 2008 (Available at:) www.ihi.org.
 

Dr. Bernstein is in the division of gastroenterology, department of medicine, Sunnybrook Health Sciences Centre; Dr. Weizman is at the Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine, and Institute of Health Policy, Management and Evaluation; Dr. Mosko is in the division of gastroenterology, department of medicine, St. Michael’s Hospital, and the Institute of Health Policy, Management, and Evaluation; Dr. Bollegala is in the division of gastroenterology, department of medicine, Women’s College Hospital; Dr. Brahmania is in the Toronto Center for Liver Diseases, division of gastroenterology, department of medicine, University Health Network; Dr. Liu is in the division of gastroenterology, department of medicine, University Health Network; Dr. Steinhart is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine and Institute of Health Policy, Management, and Evaluation; Dr. Silver is in the division of nephrology, St. Michael’s Hospital; Dr. Nguyen is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine; and Dr. Bell is in the division of internal medicine, department of medicine, Mount Sinai Hospital. All are at the University of Toronto except Dr. Hou, who is at the Houston VA Health Services Research and Development Center of Excellence, Michael DeBakey Veterans Affairs Medical Center, and the section of gastroenterology and hepatology, Baylor College of Medicine, Houston. The authors disclose no conflicts.

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In the final of a three-part series about developing and implementing a quality improvement initiative, Dr. Bernstein and his colleagues outline how such a program can be sustained and cemented into a gastroenterology practice. This mini-series has focused on community practices and presented a road map for quality improvement through descriptions of clinical vignettes – specifically focused on improving adenoma detection rates. In multiple other articles within the Toolbox series, we have described how gastroenterologists can measure and improve one of our most important outcome measures – the adenoma detection rate for screening colonoscopy. We all are aware of the Hawthorne effect (that is, observer effect) in which people modify their behavior in response to being measured or observed. The key to sustained quality improvement is to change fundamental practices once the flush of initial success fades.
 

John I. Allen, MD, MBA, AGAF

Editor in Chief

Series review

In this series, you are a community-based urban general gastroenterologist asked by hospital administration to improve your current group adenoma detection rate (ADR) of 19% to the established target of 25% among each individual endoscopist within the group during a 12-month period.

The team has implemented standardized endoscopist report cards during the past 9 months. At present, ADR has been more than 25% for all practitioners for 4 consecutive months. The quality improvement team meets to determine how to sustain the gains long term.

Sustainability of improved outcomes has been defined as: “When new ways of working and improved outcomes become the norm.”1 This incorporates a number of important concepts. “New ways of working” means that a change has been made in the way care has been provided. This includes interventions such as a new policy, implementation of a checklist, or a new clinical pathway. “Improved outcomes” implies that the result of the intervention has been measured and has demonstrated an improvement. “Become the norm” means that this change has now become a part of standard work and does not need ongoing support to continue.

Although a great deal of literature currently exists that focuses on initiation and implementation of quality improvement (QI) activities, much less has been written on sustaining efforts once the goal has been achieved. A number of reasons have been proposed for this, including stability being typically regarded as less interesting, as well as the research requiring much longer time frames for study.2 However, there is important evidence that suggests that up to 70% of long-term changes in health care organizations ultimately fail.3 This indicates a pressing need for effective strategies to sustain improved outcomes.

Challenges

A number of challenges face the sustainability phase of an intervention.2 First, the initial enthusiasm for a novel intervention wanes after time, often limiting long-term compliance if it has not become part of standard work. Second, the local or national support for a project may have changed as strategic priorities shift. This can result in a loss of leadership support and/or resources. Third, most institutions value novel ideas over a steady state, and focusing on the next initiative offers more career value for managers as compared with maintaining current practices. Finally, it is common for groups to declare victory too soon. This is defined as celebrating the first performance improvement as the final goal instead of it being the first step to long-term success.

Determining readiness for sustainability

The first step in determining readiness for sustaining an improvement is to determine whether there has been an actual improvement to sustain. This means both completing the plan-do-study-act cycles and establishing a true steady state. In addition, it needs to be demonstrated that a sustained change has occurred. The second article in this series addresses these steps in detail.4

The National Health Service (United Kingdom) Improvement Leaders’ Guide to Sustainability and Spread identifies four sets of questions to ask when determining whether a project can enter the sustainability phase.3

1. Is the (intervention) near the final stage of development? If there were room for further changes, would these completely alter the way the solution has been introduced?

2. Are the measurements demonstrating real improvement?

3. Who cares about this improvement? Is the solution representative of the wider views of those involved?

4. What policy or technological changes may render this solution redundant? When might this happen?

Once the answers to these questions have been determined and it is believed that a steady state has been achieved, it is time to move on to sustaining the intervention. Article no. 2 in our series outlines how to know whether an improvement has occurred. Although there is no single metric that can determine a project is in a steady state, it is generally believed that four or five cycles with consistent improvement and without special cause variation, along with an intervention that has been fully established, typically represent a steady state.

ACTION PLAN: For the ADR example, the answers to the questions are as follows:

 

 

1. The intervention was developed and finalized through iterative design among the QI team.

2. Performance has been consistently above target among all endoscopists for 4 consecutive months.

3. ADR is an important quality metric to individual endoscopists as well as hospital leadership. Moreover, because there are increasing models tying reimbursement to funding that are based on adherence to quality indicators, ADR will become more important.

4. If hospitals become mandated to provide scorecard data, the intervention may become redundant. However, the measurement and implications of the data still may be relevant to ongoing QI activities.

Interventions supporting sustainability

Sustainability planning is ideally started at the initiation phase of the project. When choosing a target for change, consideration of organizational factors such as strategic priorities, staff engagement, and leadership support are integral to long-term success. Factors influencing the type of intervention developed should include available funding (both long term and short term), existing information technology (IT) resources, and the ability to incorporate into existing workflow. Considering these factors from the outset will help improve a project’s long-term viability.

A number of toolkits have been produced to guide QI teams through the sustainability process. The National Health Service Institute for Innovation and Improvement has produced a comprehensive guide to sustainability.4 The guide provides advice on how to identify opportunities to increase the likelihood of sustainability for your initiative. It is accompanied by a model that can be used to predict success by dividing the factors influencing sustainability into three groups: staff, process, and organization. Each of these has a number of subcategories, and relative significance is attributed to each, with staff factors (clinical leadership engagement, senior leadership engagement, staff involvement in the change, and staff attitudes toward the change) holding the highest weighting. On the basis of the results of the model, the QI team can identify both the likelihood of success as well as opportunities for improvement.

Visual aids are another intervention that promotes sustainability. Visual cues such as posters, buttons, and magnets act as easy reminders for front-line staff. Creating a storyboard at the beginning of the project allows stakeholders to have a broad perspective on both the intervention and sustainability phases.5 Ongoing auditing and reporting of results also encourage long-term compliance. This can take the form of posting results of the intervention in the department on a regular basis as well as reports to senior administration. Regular check-ins with all stakeholders are also encouraged. This can be at a monthly staff meeting or a brief “improvement huddle” on a standing basis.

Factors influencing success

Any discussion of QI work must consider context. An understanding of the system one is working within will allow for optimization of system strengths and avoidance of pitfalls because of weaknesses. A lack of attention to context can lead to an unsuccessful project. This could be due to choosing a focus that is not in line with hospital priorities, a project that is asking staff to take on additional tasks without removing others, or developing a solution that requires funding or IT infrastructure that is not readily available.

Any organization has a number of different settings that need to be considered simultaneously. This is most simply divided into microsystem, mesosystem, and macrosystem. Microsystem is defined as the combination of a small team of people who work together on a regular basis. The mesosystem focuses on the integrated care needs of a particular group or population with the same diseases or conditions and provides support for individual microsystems. The macrosystem forms the infrastructure of the larger organization, providing the systems and governance that define the system.6 In our example, the microsystem is the endoscopy unit, including physicians, nurses, administrative support, and managers. The mesosystem is composed of the endoscopy unit in addition to the Departments of Gastroenterology and Surgery, the hospital IT team, and the Pathology Department. The macrosystem is the hospital, including senior leadership and administration. Another way of thinking about this is the microsystem is the environment most easily influenced by the individual provider, whereas the macrosystem includes the organizational-level factors that need to be taken into consideration when designing an intervention.

A great number of factors have been proposed to influence sustainability. National Health Service Scotland performed a literature review and met with subject matter experts to determine key factors that require consideration when engaging in activities to sustain and spread QI activities. They produced a guide that focused on 10 factors thought to have the greatest influence.6 Although a review of all 10 factors is beyond the scope of this review, we will highlight key ones to consider.

 

 

Innovation

The nature of the change greatly influences its likelihood of being sustained. In addition, one must consider the process of the intervention as well as those who will be impacted by the change. Core qualities that predispose to success include the following:7

1. Clear advantage compared with current ways

2. Compatibility/integration with current systems and values

3. Simplicity of the change and its implementation

4. Ease of testing

5. Observability of the change and its impact

This list highlights the point that the plan to sustain an intervention needs to start at the design phase and not once the change has been proven successful. Support among users also influences long-term success. Early adopters are those who embrace the intervention or change. Identifying the early adopters and using their support for positive publicity and momentum are integral in any sustainability effort.

ACTION PLAN: In our example, components of the intervention that would predispose to sustainability include choosing an outcome that is aligned with the hospital’s strategic focus (for example, cancer screening and prevention). ADR is already a measurable outcome at the hospital, which facilitates dissemination of results. Alternatively, some of the resistance to change may be due to the increased work to compile and distribute the scorecards monthly.

Organizational culture

Culture has been most simply defined as “the way we do things around here”.7 The approach of an organization toward QI will clearly impact its long-term viability. On a macrosystem level, interventions should ideally fit within strategic goals and priorities of organizations to garner maximum support. When promoting the intervention, it may be appropriate to focus on the benefits to the individual group (that is, cost savings to senior administration, time saved to front-line staff). Studies have shown that teams that demonstrate a strong teamwork ethic, have a positive attitude toward the intervention, and where all members know and understand their role on the team were more likely to have sustained success.8 In addition, engagement of all key stakeholders early in the process has been correlated with improved long-term outcomes. In a microsystem level, providers can choose to implement the intervention among a well-established team that works well together, ideally where there is a history or prior QI work.

Factors that may make sustaining a QI effort more challenging include interventions that increase time or costs to the organization. Many healthcare organizations may have specific targets set out from their regulatory body. If the intervention lowers the result of one of the targeted outcomes (or does not address those targets at all), it may be met with increased resistance within a system. In cases like this it is integral to use data to demonstrate to senior leadership why this still has tangible benefit to the organization.

ACTION PLAN: In our example, culture can promote sustainability on a microsystem level through reinforcing local success stories. This can be through posting of visual aids in the unit such as posters that display performance or progress boards that chart the status of the intervention. In addition, QI projects can be a regular agenda item at unit meetings, reinforcing their importance to team members.

Leadership

One key component of organizational culture is the influence of leadership. An effective leader will have both technical QI skills and strong interpersonal skills.7 Teams where all members feel comfortable making suggestions or voicing concerns are far more likely to succeed, and it is incumbent on leadership to create this environment. This concept is often termed psychological safety and has been directly linked to the inclusiveness of the leader. Team members with psychological safety are more likely to feel like active participants in the process, and this improves their long-term engagement.7,8 In addition, effective leaders create accountability systems to ensure gains are maintained. These may include regular performance reviews, reminders about the intervention, and assigning responsibility to senior level team members. Finally, celebration of accomplishments reinforces the positive impact of the time and energy invested by members of the team.9 The concept of distributed leadership is another key concept. This acknowledges that for any one intervention, there are a number of formal and informal leadership roles, and these can be filled by a number of different individuals.7

ACTION PLAN: For our ADR example, sustainability can be promoted through effective leadership. On a microsystem level, one option is the implementation of a weekly Improvement Huddle. This is a 10- to 15-minute meeting within the microsystem that is designed to review current performance and anticipate problems. All team members are encouraged to voice any concerns. On the macrosystem level, quarterly reports to senior administration and presentation of process and results at Grand Rounds may contribute to this goal.

 

 

Change management

Change management looks at how an organization approaches the new ways of working. This can be on both a social level and a technical level (often termed Organizational Infrastructure). Creating interventions that integrate with existing systems (data collection, workflow) is ideal for sustainability because it can serve to reinforce the change as standard work. In instances where the change does not immediately integrate, organizations can support change by demonstrating flexibility. This includes modification of existing technology to measure the desired outcome, development of new protocols to integrate the modified workflow, or changing job definitions of team members to demonstrate that the intervention is now considered part of daily responsibilities. Ongoing feedback also reinforces maintenance of performance. This can be through performance reviews for staff members as well as providing data to the appropriate audiences to demonstrate sustained gains.7,9

ACTION PLAN: For the ADR example, change management can contribute to sustainability through creation of a sustainable data reporting system that integrates current workflow. This will allow ongoing measurement of key metrics and is integral for long-term viability.

Summary

In this final article of a three-part series directed toward gastroenterologists interested in local QI endeavors, we selectively reviewed concepts surrounding sustainability of QI endeavors. This included determining readiness and understanding the factors that influence long-term success on both a macrosystem and microsystem level. Factors under the direct control of the individual practitioner were highlighted to give examples of specific strategies for successful sustainability.

References

1. Thomas, S., Zahn, D. Sustaining improved outcomes: a toolkit. Available at: http://nyshealthfoundation.org/resources-and-reports/resource/sustaining-improved-outcomes-a-toolkit.

2. Buchanan, D., Fitzgerald, L., Ketley, D., et al. No going back: a review of the literature on sustaining organizational change. Int. J Manag Rev. 2005;7:189-205.

3. Sustainability: model and guide. National Health Service Institute for Innovation and Improvement, Leeds, U.K.; 2007.

4. Improvement leaders’ guide to sustainability and spread. NHS Modernisation Agency. Ipswich, England: Ancient House Printing Group; 2002.

5. Nelson, E.C., Batalden, P.B., Godfrey, M.M. Quality by design: a clinical microsystems approach. Jossey-Bass, San Francisco, Calif; 2007.

6. Available at: http://www.ashpfoundation.org/lean.

7. NHS Scotland Quality Improvement Hub. The spread and sustainability of quality improvement in healthcare. 2014. Available at: http://www.qihub.scot.nhs.uk/knowledge-centre/quality-improvement-topics/spread-and-sustainability.aspx.

8. Healthcare Improvement Scotland. Quality improvement: sustainable in any organizational culture? 2013. Available at: http://www.healthcareimprovementscotland.org/previous_resources/benchmarking_report/quality_improvement_report.aspx.

9. 5 Million Lives Campaign. Getting started kit: rapid response teams. Institute for Healthcare Improvement, Cambridge, MA; 2008 (Available at:) www.ihi.org.
 

Dr. Bernstein is in the division of gastroenterology, department of medicine, Sunnybrook Health Sciences Centre; Dr. Weizman is at the Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine, and Institute of Health Policy, Management and Evaluation; Dr. Mosko is in the division of gastroenterology, department of medicine, St. Michael’s Hospital, and the Institute of Health Policy, Management, and Evaluation; Dr. Bollegala is in the division of gastroenterology, department of medicine, Women’s College Hospital; Dr. Brahmania is in the Toronto Center for Liver Diseases, division of gastroenterology, department of medicine, University Health Network; Dr. Liu is in the division of gastroenterology, department of medicine, University Health Network; Dr. Steinhart is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine and Institute of Health Policy, Management, and Evaluation; Dr. Silver is in the division of nephrology, St. Michael’s Hospital; Dr. Nguyen is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine; and Dr. Bell is in the division of internal medicine, department of medicine, Mount Sinai Hospital. All are at the University of Toronto except Dr. Hou, who is at the Houston VA Health Services Research and Development Center of Excellence, Michael DeBakey Veterans Affairs Medical Center, and the section of gastroenterology and hepatology, Baylor College of Medicine, Houston. The authors disclose no conflicts.

 

In the final of a three-part series about developing and implementing a quality improvement initiative, Dr. Bernstein and his colleagues outline how such a program can be sustained and cemented into a gastroenterology practice. This mini-series has focused on community practices and presented a road map for quality improvement through descriptions of clinical vignettes – specifically focused on improving adenoma detection rates. In multiple other articles within the Toolbox series, we have described how gastroenterologists can measure and improve one of our most important outcome measures – the adenoma detection rate for screening colonoscopy. We all are aware of the Hawthorne effect (that is, observer effect) in which people modify their behavior in response to being measured or observed. The key to sustained quality improvement is to change fundamental practices once the flush of initial success fades.
 

John I. Allen, MD, MBA, AGAF

Editor in Chief

Series review

In this series, you are a community-based urban general gastroenterologist asked by hospital administration to improve your current group adenoma detection rate (ADR) of 19% to the established target of 25% among each individual endoscopist within the group during a 12-month period.

The team has implemented standardized endoscopist report cards during the past 9 months. At present, ADR has been more than 25% for all practitioners for 4 consecutive months. The quality improvement team meets to determine how to sustain the gains long term.

Sustainability of improved outcomes has been defined as: “When new ways of working and improved outcomes become the norm.”1 This incorporates a number of important concepts. “New ways of working” means that a change has been made in the way care has been provided. This includes interventions such as a new policy, implementation of a checklist, or a new clinical pathway. “Improved outcomes” implies that the result of the intervention has been measured and has demonstrated an improvement. “Become the norm” means that this change has now become a part of standard work and does not need ongoing support to continue.

Although a great deal of literature currently exists that focuses on initiation and implementation of quality improvement (QI) activities, much less has been written on sustaining efforts once the goal has been achieved. A number of reasons have been proposed for this, including stability being typically regarded as less interesting, as well as the research requiring much longer time frames for study.2 However, there is important evidence that suggests that up to 70% of long-term changes in health care organizations ultimately fail.3 This indicates a pressing need for effective strategies to sustain improved outcomes.

Challenges

A number of challenges face the sustainability phase of an intervention.2 First, the initial enthusiasm for a novel intervention wanes after time, often limiting long-term compliance if it has not become part of standard work. Second, the local or national support for a project may have changed as strategic priorities shift. This can result in a loss of leadership support and/or resources. Third, most institutions value novel ideas over a steady state, and focusing on the next initiative offers more career value for managers as compared with maintaining current practices. Finally, it is common for groups to declare victory too soon. This is defined as celebrating the first performance improvement as the final goal instead of it being the first step to long-term success.

Determining readiness for sustainability

The first step in determining readiness for sustaining an improvement is to determine whether there has been an actual improvement to sustain. This means both completing the plan-do-study-act cycles and establishing a true steady state. In addition, it needs to be demonstrated that a sustained change has occurred. The second article in this series addresses these steps in detail.4

The National Health Service (United Kingdom) Improvement Leaders’ Guide to Sustainability and Spread identifies four sets of questions to ask when determining whether a project can enter the sustainability phase.3

1. Is the (intervention) near the final stage of development? If there were room for further changes, would these completely alter the way the solution has been introduced?

2. Are the measurements demonstrating real improvement?

3. Who cares about this improvement? Is the solution representative of the wider views of those involved?

4. What policy or technological changes may render this solution redundant? When might this happen?

Once the answers to these questions have been determined and it is believed that a steady state has been achieved, it is time to move on to sustaining the intervention. Article no. 2 in our series outlines how to know whether an improvement has occurred. Although there is no single metric that can determine a project is in a steady state, it is generally believed that four or five cycles with consistent improvement and without special cause variation, along with an intervention that has been fully established, typically represent a steady state.

ACTION PLAN: For the ADR example, the answers to the questions are as follows:

 

 

1. The intervention was developed and finalized through iterative design among the QI team.

2. Performance has been consistently above target among all endoscopists for 4 consecutive months.

3. ADR is an important quality metric to individual endoscopists as well as hospital leadership. Moreover, because there are increasing models tying reimbursement to funding that are based on adherence to quality indicators, ADR will become more important.

4. If hospitals become mandated to provide scorecard data, the intervention may become redundant. However, the measurement and implications of the data still may be relevant to ongoing QI activities.

Interventions supporting sustainability

Sustainability planning is ideally started at the initiation phase of the project. When choosing a target for change, consideration of organizational factors such as strategic priorities, staff engagement, and leadership support are integral to long-term success. Factors influencing the type of intervention developed should include available funding (both long term and short term), existing information technology (IT) resources, and the ability to incorporate into existing workflow. Considering these factors from the outset will help improve a project’s long-term viability.

A number of toolkits have been produced to guide QI teams through the sustainability process. The National Health Service Institute for Innovation and Improvement has produced a comprehensive guide to sustainability.4 The guide provides advice on how to identify opportunities to increase the likelihood of sustainability for your initiative. It is accompanied by a model that can be used to predict success by dividing the factors influencing sustainability into three groups: staff, process, and organization. Each of these has a number of subcategories, and relative significance is attributed to each, with staff factors (clinical leadership engagement, senior leadership engagement, staff involvement in the change, and staff attitudes toward the change) holding the highest weighting. On the basis of the results of the model, the QI team can identify both the likelihood of success as well as opportunities for improvement.

Visual aids are another intervention that promotes sustainability. Visual cues such as posters, buttons, and magnets act as easy reminders for front-line staff. Creating a storyboard at the beginning of the project allows stakeholders to have a broad perspective on both the intervention and sustainability phases.5 Ongoing auditing and reporting of results also encourage long-term compliance. This can take the form of posting results of the intervention in the department on a regular basis as well as reports to senior administration. Regular check-ins with all stakeholders are also encouraged. This can be at a monthly staff meeting or a brief “improvement huddle” on a standing basis.

Factors influencing success

Any discussion of QI work must consider context. An understanding of the system one is working within will allow for optimization of system strengths and avoidance of pitfalls because of weaknesses. A lack of attention to context can lead to an unsuccessful project. This could be due to choosing a focus that is not in line with hospital priorities, a project that is asking staff to take on additional tasks without removing others, or developing a solution that requires funding or IT infrastructure that is not readily available.

Any organization has a number of different settings that need to be considered simultaneously. This is most simply divided into microsystem, mesosystem, and macrosystem. Microsystem is defined as the combination of a small team of people who work together on a regular basis. The mesosystem focuses on the integrated care needs of a particular group or population with the same diseases or conditions and provides support for individual microsystems. The macrosystem forms the infrastructure of the larger organization, providing the systems and governance that define the system.6 In our example, the microsystem is the endoscopy unit, including physicians, nurses, administrative support, and managers. The mesosystem is composed of the endoscopy unit in addition to the Departments of Gastroenterology and Surgery, the hospital IT team, and the Pathology Department. The macrosystem is the hospital, including senior leadership and administration. Another way of thinking about this is the microsystem is the environment most easily influenced by the individual provider, whereas the macrosystem includes the organizational-level factors that need to be taken into consideration when designing an intervention.

A great number of factors have been proposed to influence sustainability. National Health Service Scotland performed a literature review and met with subject matter experts to determine key factors that require consideration when engaging in activities to sustain and spread QI activities. They produced a guide that focused on 10 factors thought to have the greatest influence.6 Although a review of all 10 factors is beyond the scope of this review, we will highlight key ones to consider.

 

 

Innovation

The nature of the change greatly influences its likelihood of being sustained. In addition, one must consider the process of the intervention as well as those who will be impacted by the change. Core qualities that predispose to success include the following:7

1. Clear advantage compared with current ways

2. Compatibility/integration with current systems and values

3. Simplicity of the change and its implementation

4. Ease of testing

5. Observability of the change and its impact

This list highlights the point that the plan to sustain an intervention needs to start at the design phase and not once the change has been proven successful. Support among users also influences long-term success. Early adopters are those who embrace the intervention or change. Identifying the early adopters and using their support for positive publicity and momentum are integral in any sustainability effort.

ACTION PLAN: In our example, components of the intervention that would predispose to sustainability include choosing an outcome that is aligned with the hospital’s strategic focus (for example, cancer screening and prevention). ADR is already a measurable outcome at the hospital, which facilitates dissemination of results. Alternatively, some of the resistance to change may be due to the increased work to compile and distribute the scorecards monthly.

Organizational culture

Culture has been most simply defined as “the way we do things around here”.7 The approach of an organization toward QI will clearly impact its long-term viability. On a macrosystem level, interventions should ideally fit within strategic goals and priorities of organizations to garner maximum support. When promoting the intervention, it may be appropriate to focus on the benefits to the individual group (that is, cost savings to senior administration, time saved to front-line staff). Studies have shown that teams that demonstrate a strong teamwork ethic, have a positive attitude toward the intervention, and where all members know and understand their role on the team were more likely to have sustained success.8 In addition, engagement of all key stakeholders early in the process has been correlated with improved long-term outcomes. In a microsystem level, providers can choose to implement the intervention among a well-established team that works well together, ideally where there is a history or prior QI work.

Factors that may make sustaining a QI effort more challenging include interventions that increase time or costs to the organization. Many healthcare organizations may have specific targets set out from their regulatory body. If the intervention lowers the result of one of the targeted outcomes (or does not address those targets at all), it may be met with increased resistance within a system. In cases like this it is integral to use data to demonstrate to senior leadership why this still has tangible benefit to the organization.

ACTION PLAN: In our example, culture can promote sustainability on a microsystem level through reinforcing local success stories. This can be through posting of visual aids in the unit such as posters that display performance or progress boards that chart the status of the intervention. In addition, QI projects can be a regular agenda item at unit meetings, reinforcing their importance to team members.

Leadership

One key component of organizational culture is the influence of leadership. An effective leader will have both technical QI skills and strong interpersonal skills.7 Teams where all members feel comfortable making suggestions or voicing concerns are far more likely to succeed, and it is incumbent on leadership to create this environment. This concept is often termed psychological safety and has been directly linked to the inclusiveness of the leader. Team members with psychological safety are more likely to feel like active participants in the process, and this improves their long-term engagement.7,8 In addition, effective leaders create accountability systems to ensure gains are maintained. These may include regular performance reviews, reminders about the intervention, and assigning responsibility to senior level team members. Finally, celebration of accomplishments reinforces the positive impact of the time and energy invested by members of the team.9 The concept of distributed leadership is another key concept. This acknowledges that for any one intervention, there are a number of formal and informal leadership roles, and these can be filled by a number of different individuals.7

ACTION PLAN: For our ADR example, sustainability can be promoted through effective leadership. On a microsystem level, one option is the implementation of a weekly Improvement Huddle. This is a 10- to 15-minute meeting within the microsystem that is designed to review current performance and anticipate problems. All team members are encouraged to voice any concerns. On the macrosystem level, quarterly reports to senior administration and presentation of process and results at Grand Rounds may contribute to this goal.

 

 

Change management

Change management looks at how an organization approaches the new ways of working. This can be on both a social level and a technical level (often termed Organizational Infrastructure). Creating interventions that integrate with existing systems (data collection, workflow) is ideal for sustainability because it can serve to reinforce the change as standard work. In instances where the change does not immediately integrate, organizations can support change by demonstrating flexibility. This includes modification of existing technology to measure the desired outcome, development of new protocols to integrate the modified workflow, or changing job definitions of team members to demonstrate that the intervention is now considered part of daily responsibilities. Ongoing feedback also reinforces maintenance of performance. This can be through performance reviews for staff members as well as providing data to the appropriate audiences to demonstrate sustained gains.7,9

ACTION PLAN: For the ADR example, change management can contribute to sustainability through creation of a sustainable data reporting system that integrates current workflow. This will allow ongoing measurement of key metrics and is integral for long-term viability.

Summary

In this final article of a three-part series directed toward gastroenterologists interested in local QI endeavors, we selectively reviewed concepts surrounding sustainability of QI endeavors. This included determining readiness and understanding the factors that influence long-term success on both a macrosystem and microsystem level. Factors under the direct control of the individual practitioner were highlighted to give examples of specific strategies for successful sustainability.

References

1. Thomas, S., Zahn, D. Sustaining improved outcomes: a toolkit. Available at: http://nyshealthfoundation.org/resources-and-reports/resource/sustaining-improved-outcomes-a-toolkit.

2. Buchanan, D., Fitzgerald, L., Ketley, D., et al. No going back: a review of the literature on sustaining organizational change. Int. J Manag Rev. 2005;7:189-205.

3. Sustainability: model and guide. National Health Service Institute for Innovation and Improvement, Leeds, U.K.; 2007.

4. Improvement leaders’ guide to sustainability and spread. NHS Modernisation Agency. Ipswich, England: Ancient House Printing Group; 2002.

5. Nelson, E.C., Batalden, P.B., Godfrey, M.M. Quality by design: a clinical microsystems approach. Jossey-Bass, San Francisco, Calif; 2007.

6. Available at: http://www.ashpfoundation.org/lean.

7. NHS Scotland Quality Improvement Hub. The spread and sustainability of quality improvement in healthcare. 2014. Available at: http://www.qihub.scot.nhs.uk/knowledge-centre/quality-improvement-topics/spread-and-sustainability.aspx.

8. Healthcare Improvement Scotland. Quality improvement: sustainable in any organizational culture? 2013. Available at: http://www.healthcareimprovementscotland.org/previous_resources/benchmarking_report/quality_improvement_report.aspx.

9. 5 Million Lives Campaign. Getting started kit: rapid response teams. Institute for Healthcare Improvement, Cambridge, MA; 2008 (Available at:) www.ihi.org.
 

Dr. Bernstein is in the division of gastroenterology, department of medicine, Sunnybrook Health Sciences Centre; Dr. Weizman is at the Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine, and Institute of Health Policy, Management and Evaluation; Dr. Mosko is in the division of gastroenterology, department of medicine, St. Michael’s Hospital, and the Institute of Health Policy, Management, and Evaluation; Dr. Bollegala is in the division of gastroenterology, department of medicine, Women’s College Hospital; Dr. Brahmania is in the Toronto Center for Liver Diseases, division of gastroenterology, department of medicine, University Health Network; Dr. Liu is in the division of gastroenterology, department of medicine, University Health Network; Dr. Steinhart is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine and Institute of Health Policy, Management, and Evaluation; Dr. Silver is in the division of nephrology, St. Michael’s Hospital; Dr. Nguyen is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine; and Dr. Bell is in the division of internal medicine, department of medicine, Mount Sinai Hospital. All are at the University of Toronto except Dr. Hou, who is at the Houston VA Health Services Research and Development Center of Excellence, Michael DeBakey Veterans Affairs Medical Center, and the section of gastroenterology and hepatology, Baylor College of Medicine, Houston. The authors disclose no conflicts.

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The plan-do-study-act cycle and data display

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Thu, 03/28/2019 - 14:59

 

This month’s column is the second in a series of three articles written by a group from Toronto and Houston. The series imagined that a community of gastroenterologists set out to improve the adenoma detection rates of physicians in their practice. The first article described the design and launch of the project. This month, Dr. Bollegala and her colleagues explain the plan-do-study-act (PDSA) cycle of improvement within a small practice. The PDSA cycle is a fundamental component of successful quality improvement initiatives; it allows a group to systematically analyze what works and what doesn’t. The focus of this article is squarely on small community practices (still the majority of gastrointestinal practices nationally), so its relevance is high. PDSA cycles are small, narrowly focused projects that can be accomplished by all as we strive to improve our care of the patients we serve. Next month, we will learn how to embed a quality initiative within our practices so sustained improvement can be seen.



John I. Allen, MD, MBA, AGAF

Editor in Chief

 

Article 1 of our series focused on the emergence of the adenoma detection rate (ADR) as a quality indicator for colonoscopy-based colorectal cancer screening programs.1 A target ADR of 25% has been established by several national gastroenterology societies and serves as a focus area for those seeking to develop quality improvement (QI) initiatives aimed at reducing the interval incidence of colorectal cancer.2 In this series, you are a community-based urban general gastroenterologist interested in improving your current group ADR of 19% to the established target of 25% for each individual endoscopist within the group over a 12-month period.

This article focuses on a clinician-friendly description of the plan-do-study-act (PDSA) cycle, a key construct within the Model for Improvement framework for QI initiatives. It also describes the importance and key elements of QI data reporting, including the run chart. All core concepts will be framed within the series example of the development of an institutional QI initiative for ADR improvement.
 

Plan-Do-Study-Act cycle

Conventional scientific research in health care generally is based on large-scale projects, performed over long periods of time and producing aggregate data analyzed through summary statistics. QI-related research, as it relates to PDSA, in contrast, is characterized by smaller-scale projects performed over shorter periods of time, with iterative protocols to accommodate local context and therefore optimize intervention success. As such, the framework for their development, implementation, and continual modification requires a conceptual and methodologic shift.

The PDSA cycle is characterized by four key steps. The first step is to plan. This step involves addressing the following questions: 1) what are we trying to accomplish? (aim); 2) how will we know that a change is an improvement? (measure); and 3) what changes can we make that will lead to improvement? (change). Additional considerations include ensuring that the stated goal is attainable, relevant, and that the timeline is feasible. An important aspect of the plan stage is gaining an understanding for the current local context, key participants and their roles, and areas in which performance is excelling or is challenged. This understanding is critical to conceptually linking the identified problem with its proposed solution. Formulating an impact prediction allows subsequent learning and adaptation.

The second step is to do. This step involves execution of the identified plan over a specified period of time. It also involves rigorous qualitative and quantitative data collection, allowing the research team to assess change and document unexpected events. The identification of an implementation leader or champion to ensure protocol adherence, effective communication among team members, and coordinate accurate data collection can be critical for overall success.

The third step is to study. This step requires evaluating whether a change in the outcome measure has occurred, which intervention was successful, and whether an identified change is sustained over time. It also requires interpretation of change within the local context, specifically with respect to unintended consequences, unanticipated events, and the sustainability of any gains. To interpret study findings appropriately, feedback with involved process members, endoscopists, and/or other stakeholder groups may be necessary. This can be important for explaining the results of each cycle, identifying protocol modifications for future cycles, and optimizing the opportunity for success. Studying the data generated by a QI initiative requires clear and accurate data display and rules for interpretation.

The fourth step is to act. This final step allows team members to reflect on the results generated and decide whether the same intervention should be continued, modified, or changed, thereby incorporating lessons learned from previous PDSA cycles (Figure 1).3

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Figure 1
Documentation of each PDSA cycle is an important component of the QI research process, allowing for learning that informs future cycles or initiatives, reflection, and knowledge capture.4 However, a recent systematic review published by Taylor et al.4 reported an “inconsistent approach to the application and reporting of PDSA cycles and a lack of adherence to key principles of the method.” Fewer than 20% (14 of 73) of articles reported each PDSA cycle, with 14% of articles reporting data continuously. Only 9% of articles explicitly documented a theory-based result prediction for each cycle of change. As such, caution was advised in the interpretation and implementation of studies with inadequate PDSA conduct and/or reporting. The Standards for Quality Improvement Reporting Excellence guidelines have proposed a QI-specific publication framework.5,6 However, no standardized criteria for the conduct or reporting of the PDSA framework currently exist. In addition, the PDSA cycle is limited in its reactive nature. It also may inadequately account for system/process complexity, which may lead to varying results for the same change over time.4 Finally, it does not clearly identify the most effective intervention in achieving the target, thereby preventing simplification of the overall intervention strategy.

Despite these challenges, the PDSA framework allows for small-scale and fast-paced initiative testing that reduces patient and institutional risk while minimizing the commitment of resources.4,7 Successful cycles improve stakeholder confidence in the probability for success with larger-scale implementation.

In our series example, step 1 of the PDSA cycle, plan, can be described as follows: Aim: increase the ADR of all group endoscopists to 25% over a 12-month period. Measure: Outcome: the proportion of endoscopists at your institution with an ADR greater than 25%; process – withdrawal time; balancing – staff satisfaction, patient satisfaction, and procedure time. Change: Successive cycles will institute the following: audible timers to ensure adequate withdrawal time, publication of an endoscopist-specific composite score, and training to improve inspection technique.8

In step 2 of the PDSA cycle, do, a physician member of the gastroenterology division incorporates QI into their job description and leads a change team charged with PDSA cycle 1. An administrative assistant calculates the endoscopist-specific ADRs for that month. Documentation of related events for this cycle such as unexpected physician absence, delays in polyp histology reporting, and so forth, is performed.

In step 3 of the PDSA cycle, study, the data generated will be represented on a run chart plotting the proportion of endoscopists with an ADR greater than 25% on the y-axis, and time (in monthly intervals) on the x-axis. This will be described in further detail in a later section.

In the final step of the PDSA cycle, act, continuation and modification of the tested changes can be represented as follows.
 

 

 

Displaying data

The documentation, analysis, and interpretation of data generated by multiple PDSA cycles must be displayed accurately and succinctly. The run chart has been developed as a simple technique for identifying nonrandom patterns (that is, signals), which allows QI researchers to determine the impact of each cycle of change and the stability of that change over a given time period.9 This often is contrasted with conventional statistical approaches that aggregate data and perform summary statistical comparisons at static time points. Instead, the run chart allows for an appreciation of the dynamic nature of PDSA-driven process manipulation and resulting outcome changes.

Correct interpretation of the presented data requires an understanding of common cause variation (CCV) and special cause variation (SCV). CCV occurs randomly and is present in all health care processes. It can never be eliminated completely. SCV, in contrast, is the result of external factors that are imposed on normal processes. For example, the introduction of audible timers within endoscopy rooms to ensure adequate withdrawal time may result in an increase in the ADR. The relatively stable ADR measured in both the pre-intervention and postintervention periods are subject to CCV. However, the postintervention increase in ADR is the result of SCV.10

As shown in Figure 2, the horizontal axis shows the time scale and spans the entire duration of the intervention period. The y-axis shows the outcome measure of interest. A horizontal line representing the median is shown.9 A goal line also may be depicted. Annotations to indicate the implementation of change or other important events (such as unintended consequences or unexpected events) also may be added to facilitate data interpretation.

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Figure 2
Specific rules based on standard statistics govern the objective interpretation of a run chart and allow the differentiation between random and cause-specific patterns of change.

Shift: at least six consecutive data points above or below the median line are needed (points on the median line are skipped).9 To assess a shift appropriately, at least 10 data points are required.

Trend: at least five consecutive data points all increasing in value or all decreasing in value are needed (numerically equivalent points are skipped).9

Runs: a run refers to a series of data points on one side of the median.9 If a random pattern of data points exists on the run chart, there should be an appropriate number of runs on either side of the median. Values outside of this indicate a higher probability of a nonrandom pattern.9,11

Astronomic point: this refers to a data point that subjectively is found to be obviously different from the rest and prompts consideration of the events that led to this.9

Although straightforward to construct and interpret for clinicians without statistical training, the run chart has specific limitations. It is ideal for the display of early data but cannot be used to determine its durability.9 In addition, a run chart does not reflect discrete data with no clear median.

The example run chart in Figure 2 shows that there is a shift in data points from below the median to above the median, ultimately achieving 100% group adherence to the ADR target of greater than 25%. There are only two runs for a total of 12 data points within the 12-month study period, indicating that there is a 5% or less probability that this is a random pattern.11 It appears that our interventions have resulted in incremental improvements in the ADR to exceed the target level in a nonrandom fashion. Although the cumulative effect of these interventions has been successful, it is difficult to predict the durability of this change moving forward. In addition, it would be difficult to select only a single intervention, of the many trialed, that would result in a sustained ADR of 25% or greater.

Summary and next steps

This article selectively reviews the process of change framed by the PDSA cycle. We also discuss the role of data display and interpretation using a run chart. The final article in this series will cover how to sustain change and support a culture of continuous improvement.

References

1. Corley, D.A., Jensen, C.D., Marks, A.R., et al. Adenoma detection rate and risk of colorectal cancer and death. N Engl J Med. 2014;370:1298-306.

2. Cohen, J., Schoenfeld, P., Park, W., et al. Quality indicators for colonoscopy. Gastrointest Endosc. 2015;81:31-53.

3. Module 5: Improvement Cycle. (2013). Available at: http://implementation.fpg.unc.edu/book/export/html/326. Accessed Feb. 1, 2016.

4. Taylor, M.J., McNicholas, C., Nicolay, C., et al. Systematic review of the application of the plan-do-study-act method to improve quality in healthcare. BMJ Qual Saf. 2014;23(4):290-8.

5. Davidoff, F., Batalden, P., Stevens, D. et al. Publication guidelines for quality improvement in health care: evolution of the SQUIRE project. Qual Saf Health Care. 2008;17:i3-9.

6. Ogrinc, G., Mooney, S., Estrada, C., et al. The SQUIRE (standards for Quality Improvement Reporting Excellence) guidelines for quality improvement reporting: explanation and elaboration. Qual Saf Health Care. 2008;17:i13-32.

7. Nelson, E.C., Batalden, B.P., Godfrey, M.M. Quality by design: a clinical microsystems approach. Jossey-Bass, San Francisco; 2007.

8. Coe, S.G.C.J., Diehl, N.N., Wallace, M.B. An endoscopic quality improvement program improves detection of colorectal adenomas. Am J Gastroenterol. 2013;108(2):219-26.

9. Perla, R.J., Provost, L.P., Murray, S.K. The run chart: a simple analytical tool for learning from variation in healthcare processes. BMJ Qual Saf. 2011;20:46-51.

10. Neuhauser, D., Provost, L., Bergman, B. The meaning of variation to healthcare managers, clinical and health-services researchers, and individual patients. BMJ Qual Saf. 2011;20:i36-40.

11. Swed, F.S. Eisenhart, C. Tables for testing randomness of grouping in a sequence of alternatives. Ann Math Statist. 1943;14:66-87

Dr. Bollegala is in the division of gastroenterology, department of medicine, Women’s College Hospital; Dr. Mosko is in the division of gastroenterology, department of medicine, St. Michael’s Hospital, and the Institute of Health Policy, Management, and Evaluation; Dr. Bernstein is in the division of gastroenterology, department of medicine, Sunnybrook Health Sciences Centre; Dr. Brahmania is in the Toronto Center for Liver Diseases, division of gastroenterology, department of medicine, University Health Network; Dr. Liu is in the division of gastroenterology, department of medicine, University Health Network; Dr. Steinhart is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine and Institute of Health Policy, Management, and Evaluation; Dr. Silver is in the division of nephrology, St. Michael’s Hospital; Dr. Bell is in the division of internal medicine, department of medicine, Mount Sinai Hospital; Dr. Nguyen is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine; Dr. Weizman is at the Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine, and Institute of Health Policy, Management and Evaluation. All are at the University of Toronto. Dr. Patel is in the division of gastroenterology and hepatology, department of medicine, Baylor College of Medicine, Houston. The authors disclose no conflicts.

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This month’s column is the second in a series of three articles written by a group from Toronto and Houston. The series imagined that a community of gastroenterologists set out to improve the adenoma detection rates of physicians in their practice. The first article described the design and launch of the project. This month, Dr. Bollegala and her colleagues explain the plan-do-study-act (PDSA) cycle of improvement within a small practice. The PDSA cycle is a fundamental component of successful quality improvement initiatives; it allows a group to systematically analyze what works and what doesn’t. The focus of this article is squarely on small community practices (still the majority of gastrointestinal practices nationally), so its relevance is high. PDSA cycles are small, narrowly focused projects that can be accomplished by all as we strive to improve our care of the patients we serve. Next month, we will learn how to embed a quality initiative within our practices so sustained improvement can be seen.



John I. Allen, MD, MBA, AGAF

Editor in Chief

 

Article 1 of our series focused on the emergence of the adenoma detection rate (ADR) as a quality indicator for colonoscopy-based colorectal cancer screening programs.1 A target ADR of 25% has been established by several national gastroenterology societies and serves as a focus area for those seeking to develop quality improvement (QI) initiatives aimed at reducing the interval incidence of colorectal cancer.2 In this series, you are a community-based urban general gastroenterologist interested in improving your current group ADR of 19% to the established target of 25% for each individual endoscopist within the group over a 12-month period.

This article focuses on a clinician-friendly description of the plan-do-study-act (PDSA) cycle, a key construct within the Model for Improvement framework for QI initiatives. It also describes the importance and key elements of QI data reporting, including the run chart. All core concepts will be framed within the series example of the development of an institutional QI initiative for ADR improvement.
 

Plan-Do-Study-Act cycle

Conventional scientific research in health care generally is based on large-scale projects, performed over long periods of time and producing aggregate data analyzed through summary statistics. QI-related research, as it relates to PDSA, in contrast, is characterized by smaller-scale projects performed over shorter periods of time, with iterative protocols to accommodate local context and therefore optimize intervention success. As such, the framework for their development, implementation, and continual modification requires a conceptual and methodologic shift.

The PDSA cycle is characterized by four key steps. The first step is to plan. This step involves addressing the following questions: 1) what are we trying to accomplish? (aim); 2) how will we know that a change is an improvement? (measure); and 3) what changes can we make that will lead to improvement? (change). Additional considerations include ensuring that the stated goal is attainable, relevant, and that the timeline is feasible. An important aspect of the plan stage is gaining an understanding for the current local context, key participants and their roles, and areas in which performance is excelling or is challenged. This understanding is critical to conceptually linking the identified problem with its proposed solution. Formulating an impact prediction allows subsequent learning and adaptation.

The second step is to do. This step involves execution of the identified plan over a specified period of time. It also involves rigorous qualitative and quantitative data collection, allowing the research team to assess change and document unexpected events. The identification of an implementation leader or champion to ensure protocol adherence, effective communication among team members, and coordinate accurate data collection can be critical for overall success.

The third step is to study. This step requires evaluating whether a change in the outcome measure has occurred, which intervention was successful, and whether an identified change is sustained over time. It also requires interpretation of change within the local context, specifically with respect to unintended consequences, unanticipated events, and the sustainability of any gains. To interpret study findings appropriately, feedback with involved process members, endoscopists, and/or other stakeholder groups may be necessary. This can be important for explaining the results of each cycle, identifying protocol modifications for future cycles, and optimizing the opportunity for success. Studying the data generated by a QI initiative requires clear and accurate data display and rules for interpretation.

The fourth step is to act. This final step allows team members to reflect on the results generated and decide whether the same intervention should be continued, modified, or changed, thereby incorporating lessons learned from previous PDSA cycles (Figure 1).3

AGA Institute
Figure 1
Documentation of each PDSA cycle is an important component of the QI research process, allowing for learning that informs future cycles or initiatives, reflection, and knowledge capture.4 However, a recent systematic review published by Taylor et al.4 reported an “inconsistent approach to the application and reporting of PDSA cycles and a lack of adherence to key principles of the method.” Fewer than 20% (14 of 73) of articles reported each PDSA cycle, with 14% of articles reporting data continuously. Only 9% of articles explicitly documented a theory-based result prediction for each cycle of change. As such, caution was advised in the interpretation and implementation of studies with inadequate PDSA conduct and/or reporting. The Standards for Quality Improvement Reporting Excellence guidelines have proposed a QI-specific publication framework.5,6 However, no standardized criteria for the conduct or reporting of the PDSA framework currently exist. In addition, the PDSA cycle is limited in its reactive nature. It also may inadequately account for system/process complexity, which may lead to varying results for the same change over time.4 Finally, it does not clearly identify the most effective intervention in achieving the target, thereby preventing simplification of the overall intervention strategy.

Despite these challenges, the PDSA framework allows for small-scale and fast-paced initiative testing that reduces patient and institutional risk while minimizing the commitment of resources.4,7 Successful cycles improve stakeholder confidence in the probability for success with larger-scale implementation.

In our series example, step 1 of the PDSA cycle, plan, can be described as follows: Aim: increase the ADR of all group endoscopists to 25% over a 12-month period. Measure: Outcome: the proportion of endoscopists at your institution with an ADR greater than 25%; process – withdrawal time; balancing – staff satisfaction, patient satisfaction, and procedure time. Change: Successive cycles will institute the following: audible timers to ensure adequate withdrawal time, publication of an endoscopist-specific composite score, and training to improve inspection technique.8

In step 2 of the PDSA cycle, do, a physician member of the gastroenterology division incorporates QI into their job description and leads a change team charged with PDSA cycle 1. An administrative assistant calculates the endoscopist-specific ADRs for that month. Documentation of related events for this cycle such as unexpected physician absence, delays in polyp histology reporting, and so forth, is performed.

In step 3 of the PDSA cycle, study, the data generated will be represented on a run chart plotting the proportion of endoscopists with an ADR greater than 25% on the y-axis, and time (in monthly intervals) on the x-axis. This will be described in further detail in a later section.

In the final step of the PDSA cycle, act, continuation and modification of the tested changes can be represented as follows.
 

 

 

Displaying data

The documentation, analysis, and interpretation of data generated by multiple PDSA cycles must be displayed accurately and succinctly. The run chart has been developed as a simple technique for identifying nonrandom patterns (that is, signals), which allows QI researchers to determine the impact of each cycle of change and the stability of that change over a given time period.9 This often is contrasted with conventional statistical approaches that aggregate data and perform summary statistical comparisons at static time points. Instead, the run chart allows for an appreciation of the dynamic nature of PDSA-driven process manipulation and resulting outcome changes.

Correct interpretation of the presented data requires an understanding of common cause variation (CCV) and special cause variation (SCV). CCV occurs randomly and is present in all health care processes. It can never be eliminated completely. SCV, in contrast, is the result of external factors that are imposed on normal processes. For example, the introduction of audible timers within endoscopy rooms to ensure adequate withdrawal time may result in an increase in the ADR. The relatively stable ADR measured in both the pre-intervention and postintervention periods are subject to CCV. However, the postintervention increase in ADR is the result of SCV.10

As shown in Figure 2, the horizontal axis shows the time scale and spans the entire duration of the intervention period. The y-axis shows the outcome measure of interest. A horizontal line representing the median is shown.9 A goal line also may be depicted. Annotations to indicate the implementation of change or other important events (such as unintended consequences or unexpected events) also may be added to facilitate data interpretation.

AGA Institute
Figure 2
Specific rules based on standard statistics govern the objective interpretation of a run chart and allow the differentiation between random and cause-specific patterns of change.

Shift: at least six consecutive data points above or below the median line are needed (points on the median line are skipped).9 To assess a shift appropriately, at least 10 data points are required.

Trend: at least five consecutive data points all increasing in value or all decreasing in value are needed (numerically equivalent points are skipped).9

Runs: a run refers to a series of data points on one side of the median.9 If a random pattern of data points exists on the run chart, there should be an appropriate number of runs on either side of the median. Values outside of this indicate a higher probability of a nonrandom pattern.9,11

Astronomic point: this refers to a data point that subjectively is found to be obviously different from the rest and prompts consideration of the events that led to this.9

Although straightforward to construct and interpret for clinicians without statistical training, the run chart has specific limitations. It is ideal for the display of early data but cannot be used to determine its durability.9 In addition, a run chart does not reflect discrete data with no clear median.

The example run chart in Figure 2 shows that there is a shift in data points from below the median to above the median, ultimately achieving 100% group adherence to the ADR target of greater than 25%. There are only two runs for a total of 12 data points within the 12-month study period, indicating that there is a 5% or less probability that this is a random pattern.11 It appears that our interventions have resulted in incremental improvements in the ADR to exceed the target level in a nonrandom fashion. Although the cumulative effect of these interventions has been successful, it is difficult to predict the durability of this change moving forward. In addition, it would be difficult to select only a single intervention, of the many trialed, that would result in a sustained ADR of 25% or greater.

Summary and next steps

This article selectively reviews the process of change framed by the PDSA cycle. We also discuss the role of data display and interpretation using a run chart. The final article in this series will cover how to sustain change and support a culture of continuous improvement.

References

1. Corley, D.A., Jensen, C.D., Marks, A.R., et al. Adenoma detection rate and risk of colorectal cancer and death. N Engl J Med. 2014;370:1298-306.

2. Cohen, J., Schoenfeld, P., Park, W., et al. Quality indicators for colonoscopy. Gastrointest Endosc. 2015;81:31-53.

3. Module 5: Improvement Cycle. (2013). Available at: http://implementation.fpg.unc.edu/book/export/html/326. Accessed Feb. 1, 2016.

4. Taylor, M.J., McNicholas, C., Nicolay, C., et al. Systematic review of the application of the plan-do-study-act method to improve quality in healthcare. BMJ Qual Saf. 2014;23(4):290-8.

5. Davidoff, F., Batalden, P., Stevens, D. et al. Publication guidelines for quality improvement in health care: evolution of the SQUIRE project. Qual Saf Health Care. 2008;17:i3-9.

6. Ogrinc, G., Mooney, S., Estrada, C., et al. The SQUIRE (standards for Quality Improvement Reporting Excellence) guidelines for quality improvement reporting: explanation and elaboration. Qual Saf Health Care. 2008;17:i13-32.

7. Nelson, E.C., Batalden, B.P., Godfrey, M.M. Quality by design: a clinical microsystems approach. Jossey-Bass, San Francisco; 2007.

8. Coe, S.G.C.J., Diehl, N.N., Wallace, M.B. An endoscopic quality improvement program improves detection of colorectal adenomas. Am J Gastroenterol. 2013;108(2):219-26.

9. Perla, R.J., Provost, L.P., Murray, S.K. The run chart: a simple analytical tool for learning from variation in healthcare processes. BMJ Qual Saf. 2011;20:46-51.

10. Neuhauser, D., Provost, L., Bergman, B. The meaning of variation to healthcare managers, clinical and health-services researchers, and individual patients. BMJ Qual Saf. 2011;20:i36-40.

11. Swed, F.S. Eisenhart, C. Tables for testing randomness of grouping in a sequence of alternatives. Ann Math Statist. 1943;14:66-87

Dr. Bollegala is in the division of gastroenterology, department of medicine, Women’s College Hospital; Dr. Mosko is in the division of gastroenterology, department of medicine, St. Michael’s Hospital, and the Institute of Health Policy, Management, and Evaluation; Dr. Bernstein is in the division of gastroenterology, department of medicine, Sunnybrook Health Sciences Centre; Dr. Brahmania is in the Toronto Center for Liver Diseases, division of gastroenterology, department of medicine, University Health Network; Dr. Liu is in the division of gastroenterology, department of medicine, University Health Network; Dr. Steinhart is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine and Institute of Health Policy, Management, and Evaluation; Dr. Silver is in the division of nephrology, St. Michael’s Hospital; Dr. Bell is in the division of internal medicine, department of medicine, Mount Sinai Hospital; Dr. Nguyen is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine; Dr. Weizman is at the Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine, and Institute of Health Policy, Management and Evaluation. All are at the University of Toronto. Dr. Patel is in the division of gastroenterology and hepatology, department of medicine, Baylor College of Medicine, Houston. The authors disclose no conflicts.

 

This month’s column is the second in a series of three articles written by a group from Toronto and Houston. The series imagined that a community of gastroenterologists set out to improve the adenoma detection rates of physicians in their practice. The first article described the design and launch of the project. This month, Dr. Bollegala and her colleagues explain the plan-do-study-act (PDSA) cycle of improvement within a small practice. The PDSA cycle is a fundamental component of successful quality improvement initiatives; it allows a group to systematically analyze what works and what doesn’t. The focus of this article is squarely on small community practices (still the majority of gastrointestinal practices nationally), so its relevance is high. PDSA cycles are small, narrowly focused projects that can be accomplished by all as we strive to improve our care of the patients we serve. Next month, we will learn how to embed a quality initiative within our practices so sustained improvement can be seen.



John I. Allen, MD, MBA, AGAF

Editor in Chief

 

Article 1 of our series focused on the emergence of the adenoma detection rate (ADR) as a quality indicator for colonoscopy-based colorectal cancer screening programs.1 A target ADR of 25% has been established by several national gastroenterology societies and serves as a focus area for those seeking to develop quality improvement (QI) initiatives aimed at reducing the interval incidence of colorectal cancer.2 In this series, you are a community-based urban general gastroenterologist interested in improving your current group ADR of 19% to the established target of 25% for each individual endoscopist within the group over a 12-month period.

This article focuses on a clinician-friendly description of the plan-do-study-act (PDSA) cycle, a key construct within the Model for Improvement framework for QI initiatives. It also describes the importance and key elements of QI data reporting, including the run chart. All core concepts will be framed within the series example of the development of an institutional QI initiative for ADR improvement.
 

Plan-Do-Study-Act cycle

Conventional scientific research in health care generally is based on large-scale projects, performed over long periods of time and producing aggregate data analyzed through summary statistics. QI-related research, as it relates to PDSA, in contrast, is characterized by smaller-scale projects performed over shorter periods of time, with iterative protocols to accommodate local context and therefore optimize intervention success. As such, the framework for their development, implementation, and continual modification requires a conceptual and methodologic shift.

The PDSA cycle is characterized by four key steps. The first step is to plan. This step involves addressing the following questions: 1) what are we trying to accomplish? (aim); 2) how will we know that a change is an improvement? (measure); and 3) what changes can we make that will lead to improvement? (change). Additional considerations include ensuring that the stated goal is attainable, relevant, and that the timeline is feasible. An important aspect of the plan stage is gaining an understanding for the current local context, key participants and their roles, and areas in which performance is excelling or is challenged. This understanding is critical to conceptually linking the identified problem with its proposed solution. Formulating an impact prediction allows subsequent learning and adaptation.

The second step is to do. This step involves execution of the identified plan over a specified period of time. It also involves rigorous qualitative and quantitative data collection, allowing the research team to assess change and document unexpected events. The identification of an implementation leader or champion to ensure protocol adherence, effective communication among team members, and coordinate accurate data collection can be critical for overall success.

The third step is to study. This step requires evaluating whether a change in the outcome measure has occurred, which intervention was successful, and whether an identified change is sustained over time. It also requires interpretation of change within the local context, specifically with respect to unintended consequences, unanticipated events, and the sustainability of any gains. To interpret study findings appropriately, feedback with involved process members, endoscopists, and/or other stakeholder groups may be necessary. This can be important for explaining the results of each cycle, identifying protocol modifications for future cycles, and optimizing the opportunity for success. Studying the data generated by a QI initiative requires clear and accurate data display and rules for interpretation.

The fourth step is to act. This final step allows team members to reflect on the results generated and decide whether the same intervention should be continued, modified, or changed, thereby incorporating lessons learned from previous PDSA cycles (Figure 1).3

AGA Institute
Figure 1
Documentation of each PDSA cycle is an important component of the QI research process, allowing for learning that informs future cycles or initiatives, reflection, and knowledge capture.4 However, a recent systematic review published by Taylor et al.4 reported an “inconsistent approach to the application and reporting of PDSA cycles and a lack of adherence to key principles of the method.” Fewer than 20% (14 of 73) of articles reported each PDSA cycle, with 14% of articles reporting data continuously. Only 9% of articles explicitly documented a theory-based result prediction for each cycle of change. As such, caution was advised in the interpretation and implementation of studies with inadequate PDSA conduct and/or reporting. The Standards for Quality Improvement Reporting Excellence guidelines have proposed a QI-specific publication framework.5,6 However, no standardized criteria for the conduct or reporting of the PDSA framework currently exist. In addition, the PDSA cycle is limited in its reactive nature. It also may inadequately account for system/process complexity, which may lead to varying results for the same change over time.4 Finally, it does not clearly identify the most effective intervention in achieving the target, thereby preventing simplification of the overall intervention strategy.

Despite these challenges, the PDSA framework allows for small-scale and fast-paced initiative testing that reduces patient and institutional risk while minimizing the commitment of resources.4,7 Successful cycles improve stakeholder confidence in the probability for success with larger-scale implementation.

In our series example, step 1 of the PDSA cycle, plan, can be described as follows: Aim: increase the ADR of all group endoscopists to 25% over a 12-month period. Measure: Outcome: the proportion of endoscopists at your institution with an ADR greater than 25%; process – withdrawal time; balancing – staff satisfaction, patient satisfaction, and procedure time. Change: Successive cycles will institute the following: audible timers to ensure adequate withdrawal time, publication of an endoscopist-specific composite score, and training to improve inspection technique.8

In step 2 of the PDSA cycle, do, a physician member of the gastroenterology division incorporates QI into their job description and leads a change team charged with PDSA cycle 1. An administrative assistant calculates the endoscopist-specific ADRs for that month. Documentation of related events for this cycle such as unexpected physician absence, delays in polyp histology reporting, and so forth, is performed.

In step 3 of the PDSA cycle, study, the data generated will be represented on a run chart plotting the proportion of endoscopists with an ADR greater than 25% on the y-axis, and time (in monthly intervals) on the x-axis. This will be described in further detail in a later section.

In the final step of the PDSA cycle, act, continuation and modification of the tested changes can be represented as follows.
 

 

 

Displaying data

The documentation, analysis, and interpretation of data generated by multiple PDSA cycles must be displayed accurately and succinctly. The run chart has been developed as a simple technique for identifying nonrandom patterns (that is, signals), which allows QI researchers to determine the impact of each cycle of change and the stability of that change over a given time period.9 This often is contrasted with conventional statistical approaches that aggregate data and perform summary statistical comparisons at static time points. Instead, the run chart allows for an appreciation of the dynamic nature of PDSA-driven process manipulation and resulting outcome changes.

Correct interpretation of the presented data requires an understanding of common cause variation (CCV) and special cause variation (SCV). CCV occurs randomly and is present in all health care processes. It can never be eliminated completely. SCV, in contrast, is the result of external factors that are imposed on normal processes. For example, the introduction of audible timers within endoscopy rooms to ensure adequate withdrawal time may result in an increase in the ADR. The relatively stable ADR measured in both the pre-intervention and postintervention periods are subject to CCV. However, the postintervention increase in ADR is the result of SCV.10

As shown in Figure 2, the horizontal axis shows the time scale and spans the entire duration of the intervention period. The y-axis shows the outcome measure of interest. A horizontal line representing the median is shown.9 A goal line also may be depicted. Annotations to indicate the implementation of change or other important events (such as unintended consequences or unexpected events) also may be added to facilitate data interpretation.

AGA Institute
Figure 2
Specific rules based on standard statistics govern the objective interpretation of a run chart and allow the differentiation between random and cause-specific patterns of change.

Shift: at least six consecutive data points above or below the median line are needed (points on the median line are skipped).9 To assess a shift appropriately, at least 10 data points are required.

Trend: at least five consecutive data points all increasing in value or all decreasing in value are needed (numerically equivalent points are skipped).9

Runs: a run refers to a series of data points on one side of the median.9 If a random pattern of data points exists on the run chart, there should be an appropriate number of runs on either side of the median. Values outside of this indicate a higher probability of a nonrandom pattern.9,11

Astronomic point: this refers to a data point that subjectively is found to be obviously different from the rest and prompts consideration of the events that led to this.9

Although straightforward to construct and interpret for clinicians without statistical training, the run chart has specific limitations. It is ideal for the display of early data but cannot be used to determine its durability.9 In addition, a run chart does not reflect discrete data with no clear median.

The example run chart in Figure 2 shows that there is a shift in data points from below the median to above the median, ultimately achieving 100% group adherence to the ADR target of greater than 25%. There are only two runs for a total of 12 data points within the 12-month study period, indicating that there is a 5% or less probability that this is a random pattern.11 It appears that our interventions have resulted in incremental improvements in the ADR to exceed the target level in a nonrandom fashion. Although the cumulative effect of these interventions has been successful, it is difficult to predict the durability of this change moving forward. In addition, it would be difficult to select only a single intervention, of the many trialed, that would result in a sustained ADR of 25% or greater.

Summary and next steps

This article selectively reviews the process of change framed by the PDSA cycle. We also discuss the role of data display and interpretation using a run chart. The final article in this series will cover how to sustain change and support a culture of continuous improvement.

References

1. Corley, D.A., Jensen, C.D., Marks, A.R., et al. Adenoma detection rate and risk of colorectal cancer and death. N Engl J Med. 2014;370:1298-306.

2. Cohen, J., Schoenfeld, P., Park, W., et al. Quality indicators for colonoscopy. Gastrointest Endosc. 2015;81:31-53.

3. Module 5: Improvement Cycle. (2013). Available at: http://implementation.fpg.unc.edu/book/export/html/326. Accessed Feb. 1, 2016.

4. Taylor, M.J., McNicholas, C., Nicolay, C., et al. Systematic review of the application of the plan-do-study-act method to improve quality in healthcare. BMJ Qual Saf. 2014;23(4):290-8.

5. Davidoff, F., Batalden, P., Stevens, D. et al. Publication guidelines for quality improvement in health care: evolution of the SQUIRE project. Qual Saf Health Care. 2008;17:i3-9.

6. Ogrinc, G., Mooney, S., Estrada, C., et al. The SQUIRE (standards for Quality Improvement Reporting Excellence) guidelines for quality improvement reporting: explanation and elaboration. Qual Saf Health Care. 2008;17:i13-32.

7. Nelson, E.C., Batalden, B.P., Godfrey, M.M. Quality by design: a clinical microsystems approach. Jossey-Bass, San Francisco; 2007.

8. Coe, S.G.C.J., Diehl, N.N., Wallace, M.B. An endoscopic quality improvement program improves detection of colorectal adenomas. Am J Gastroenterol. 2013;108(2):219-26.

9. Perla, R.J., Provost, L.P., Murray, S.K. The run chart: a simple analytical tool for learning from variation in healthcare processes. BMJ Qual Saf. 2011;20:46-51.

10. Neuhauser, D., Provost, L., Bergman, B. The meaning of variation to healthcare managers, clinical and health-services researchers, and individual patients. BMJ Qual Saf. 2011;20:i36-40.

11. Swed, F.S. Eisenhart, C. Tables for testing randomness of grouping in a sequence of alternatives. Ann Math Statist. 1943;14:66-87

Dr. Bollegala is in the division of gastroenterology, department of medicine, Women’s College Hospital; Dr. Mosko is in the division of gastroenterology, department of medicine, St. Michael’s Hospital, and the Institute of Health Policy, Management, and Evaluation; Dr. Bernstein is in the division of gastroenterology, department of medicine, Sunnybrook Health Sciences Centre; Dr. Brahmania is in the Toronto Center for Liver Diseases, division of gastroenterology, department of medicine, University Health Network; Dr. Liu is in the division of gastroenterology, department of medicine, University Health Network; Dr. Steinhart is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine and Institute of Health Policy, Management, and Evaluation; Dr. Silver is in the division of nephrology, St. Michael’s Hospital; Dr. Bell is in the division of internal medicine, department of medicine, Mount Sinai Hospital; Dr. Nguyen is at Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine; Dr. Weizman is at the Mount Sinai Hospital Centre for Inflammatory Bowel Disease, department of medicine, and Institute of Health Policy, Management and Evaluation. All are at the University of Toronto. Dr. Patel is in the division of gastroenterology and hepatology, department of medicine, Baylor College of Medicine, Houston. The authors disclose no conflicts.

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