Anemia

Micrograph showing MDS

The protein p300 may prevent the transformation from myelodysplastic syndromes (MDS) to acute myeloid leukemia (AML), according to research published in Leukemia.

Researchers found that loss of p300 “markedly” increased leukemogenesis in a mouse model of MDS.

“The loss of p300 allows these defective [MDS] cells to grow and become leukemic,” said study author Stephen Nimer, MD, of Sylvester Comprehensive Cancer Center in Miami, Florida.

“This work offers us a window into AML, which we are now going to try to exploit.”

Previous research suggested that p300 and CBP (both histone lysine acetyltransferases) may be tumor suppressors. The current study indicates that, in the context of MDS, that is only true for p300.

The researchers evaluated the effects of deleting both p300 and CBP in Nup98-HoxD13 (NHD13) transgenic mice, a model of human MDS.

The team found that p300 deletion, but not CBP deletion, accelerated leukemogenesis in the mice.

“When we eliminated p300, 100% of the mice developed leukemia,” Dr Nimer said. “It indicated that, under this specific circumstance, p300 is a tumor suppressor, offering great insight into how MDS converts to leukemia. It was quite surprising that CBP plays no role at all.”

The researchers also found that deleting p300 restored the ability of NHD13-expressing hematopoietic stem and progenitor cells (HSPCs) to self-renew, and p300 deletion decreased apoptosis.

“While investigating how p300 functions in MDS cells, we found that MDS cells do not grow well in the lab,” Dr Nimer said. “However, when you eliminate p300, suddenly, the cells continue to grow.”

On the other hand, deletion of p300 did not have a significant effect on wild-type hematopoiesis.

Finally, the researchers found that p300 deletion enhanced cytokine signaling in NHD13-expressing HSPCs. They observed enhanced activation of the MAPK and JAK/STAT pathways in HSPCs isolated from NHD13 transgenic mice.

The team said more research is needed to understand exactly how p300 controls MDS cells, but these findings could ultimately help MDS patients avoid AML.

“Other than chemotherapy, right now, there’s no way to prevent MDS from developing into myeloid leukemia,” Dr Nimer said. “However, drugs are being developed that can promote p300 function and possibly prevent MDS patients from developing leukemia.”

Micrograph showing MDS

The protein p300 may prevent the transformation from myelodysplastic syndromes (MDS) to acute myeloid leukemia (AML), according to research published in Leukemia.

Researchers found that loss of p300 “markedly” increased leukemogenesis in a mouse model of MDS.

“The loss of p300 allows these defective [MDS] cells to grow and become leukemic,” said study author Stephen Nimer, MD, of Sylvester Comprehensive Cancer Center in Miami, Florida.

“This work offers us a window into AML, which we are now going to try to exploit.”

Previous research suggested that p300 and CBP (both histone lysine acetyltransferases) may be tumor suppressors. The current study indicates that, in the context of MDS, that is only true for p300.

The researchers evaluated the effects of deleting both p300 and CBP in Nup98-HoxD13 (NHD13) transgenic mice, a model of human MDS.

The team found that p300 deletion, but not CBP deletion, accelerated leukemogenesis in the mice.

“When we eliminated p300, 100% of the mice developed leukemia,” Dr Nimer said. “It indicated that, under this specific circumstance, p300 is a tumor suppressor, offering great insight into how MDS converts to leukemia. It was quite surprising that CBP plays no role at all.”

The researchers also found that deleting p300 restored the ability of NHD13-expressing hematopoietic stem and progenitor cells (HSPCs) to self-renew, and p300 deletion decreased apoptosis.

“While investigating how p300 functions in MDS cells, we found that MDS cells do not grow well in the lab,” Dr Nimer said. “However, when you eliminate p300, suddenly, the cells continue to grow.”

On the other hand, deletion of p300 did not have a significant effect on wild-type hematopoiesis.

Finally, the researchers found that p300 deletion enhanced cytokine signaling in NHD13-expressing HSPCs. They observed enhanced activation of the MAPK and JAK/STAT pathways in HSPCs isolated from NHD13 transgenic mice.

The team said more research is needed to understand exactly how p300 controls MDS cells, but these findings could ultimately help MDS patients avoid AML.

“Other than chemotherapy, right now, there’s no way to prevent MDS from developing into myeloid leukemia,” Dr Nimer said. “However, drugs are being developed that can promote p300 function and possibly prevent MDS patients from developing leukemia.”

Micrograph showing MDS

The protein p300 may prevent the transformation from myelodysplastic syndromes (MDS) to acute myeloid leukemia (AML), according to research published in Leukemia.

Researchers found that loss of p300 “markedly” increased leukemogenesis in a mouse model of MDS.

“The loss of p300 allows these defective [MDS] cells to grow and become leukemic,” said study author Stephen Nimer, MD, of Sylvester Comprehensive Cancer Center in Miami, Florida.

“This work offers us a window into AML, which we are now going to try to exploit.”

Previous research suggested that p300 and CBP (both histone lysine acetyltransferases) may be tumor suppressors. The current study indicates that, in the context of MDS, that is only true for p300.

The researchers evaluated the effects of deleting both p300 and CBP in Nup98-HoxD13 (NHD13) transgenic mice, a model of human MDS.

The team found that p300 deletion, but not CBP deletion, accelerated leukemogenesis in the mice.

“When we eliminated p300, 100% of the mice developed leukemia,” Dr Nimer said. “It indicated that, under this specific circumstance, p300 is a tumor suppressor, offering great insight into how MDS converts to leukemia. It was quite surprising that CBP plays no role at all.”

The researchers also found that deleting p300 restored the ability of NHD13-expressing hematopoietic stem and progenitor cells (HSPCs) to self-renew, and p300 deletion decreased apoptosis.

“While investigating how p300 functions in MDS cells, we found that MDS cells do not grow well in the lab,” Dr Nimer said. “However, when you eliminate p300, suddenly, the cells continue to grow.”

On the other hand, deletion of p300 did not have a significant effect on wild-type hematopoiesis.

Finally, the researchers found that p300 deletion enhanced cytokine signaling in NHD13-expressing HSPCs. They observed enhanced activation of the MAPK and JAK/STAT pathways in HSPCs isolated from NHD13 transgenic mice.

The team said more research is needed to understand exactly how p300 controls MDS cells, but these findings could ultimately help MDS patients avoid AML.

“Other than chemotherapy, right now, there’s no way to prevent MDS from developing into myeloid leukemia,” Dr Nimer said. “However, drugs are being developed that can promote p300 function and possibly prevent MDS patients from developing leukemia.”

Lab mouse

The lungs may play a previously unrecognized role in blood production, according to preclinical research published in Nature.

Researchers discovered large numbers of megakaryocytes in the lungs of mice and found these cells produced roughly half of the animals’ platelets.

The team also identified a pool of hematopoietic progenitors in the extravascular spaces of mouse lungs that were capable of multi-lineage bone marrow reconstitution.

“This finding definitely suggests a more sophisticated view of the lungs—that they’re not just for respiration but also a key partner in formation of crucial aspects of the blood,” said study author Mark R. Looney, MD, of the University of California - San Francisco.

“What we’ve observed here in mice strongly suggests the lung may play a key role in blood formation in humans as well.”

The researchers believe these findings could have major implications for understanding diseases in which patients suffer from thrombocytopenia.

Imaging reveals surprise

This research was made possible by a refinement of a technique known as 2-photon intravital imaging. This approach allowed the researchers to visualize the behavior of individual cells within the blood vessels of a living mouse lung.

Dr Looney and his colleagues used the technique to examine interactions between the immune system and circulating platelets in the lungs in a mouse strain engineered so that platelets emit bright green fluorescence (GFP+).

In this way, the team noticed a large population of megakaryocytes in the lung vasculature. Though megakaryocytes had been observed in the lung before, they were generally thought to live and produce platelets primarily in the bone marrow.

“When we discovered this massive population of megakaryocytes that appeared to be living in the lung, we realized we had to follow this up,” said study author Emma Lefrançais, PhD, a postdoctoral researcher in Dr Looney’s lab.

More detailed imaging sessions revealed megakaryocytes in the act of producing more than 10 million platelets per hour within the lung vasculature. This suggests that roughly half of a mouse’s total platelet production occurs in the lung, not the bone marrow, as researchers had long presumed.

Subsequent experiments also revealed a variety of previously overlooked hematopoietic progenitors outside the lung vasculature.

Transplants provide more insight

The discovery of megakaryocytes and hematopoietic progenitors in the lung raised questions about how these cells move back and forth between the lung and bone marrow. To address these questions, the researchers conducted a set of lung transplant studies.

The team transplanted lungs from wild-type mice into mice with GFP+ megakaryocytes and vice-versa. The researchers said they observed proplatelet formation from GFP+ megakaryocytes in the lung vasculature of the GFP+ mice but not in the wild-type mice.

This suggests the megakaryocytes releasing platelets in the lung circulation originate from outside the lungs, the researchers said. And subsequent experiments suggested the megakaryocytes originate in the bone marrow.

“It’s fascinating that megakaryocytes travel all the way from the bone marrow to the lungs to produce platelets,” said Guadalupe Ortiz-Muñoz, PhD, a postdoctoral researcher in Dr Looney’s lab.

“It’s possible that the lung is an ideal bioreactor for platelet production because of the mechanical force of the blood, or perhaps because of some molecular signaling we don’t yet know about.”

In another experiment, the researchers transplanted lungs with GFP+ megakaryocyte progenitors into mutant mice with low platelet counts.

The transplants successfully restored platelet levels to normal, an effect that persisted over a few months of observation—much longer than the lifespan of individual megakaryocytes or platelets.

To the researchers, this indicated that resident megakaryocyte progenitors in the transplanted lungs had become activated by the recipient mouse’s low platelet counts and had produced healthy megakaryocytes to restore proper platelet production.

Finally, the researchers tested whether lung hematopoietic progenitors were capable of multi-lineage bone marrow reconstitution.

They found that cells originating from transplanted lungs traveled to damaged bone marrow and contributed to the production of platelets and other blood cells, including neutrophils, B cells, and T cells.

The researchers said these experiments suggest the lungs play host to a variety of hematopoietic progenitors capable of reconstituting damaged bone marrow and restoring the production of many components of the blood.

“To our knowledge, this is the first description of blood progenitors resident in the lung, and it raises a lot of questions with clinical relevance for the millions of people who suffer from thrombocytopenia,” Dr Looney said.

In particular, the study suggests that researchers who have proposed treating platelet diseases with platelets produced from engineered megakaryocytes should look to the lungs as a resource for platelet production, Dr Looney noted.

The study also presents new avenues of research for stem cell biologists to explore how the bone marrow and lung collaborate to produce a healthy blood system through the mutual exchange of stem cells.

“These observations alter existing paradigms regarding blood cell formation, lung biology and disease, and transplantation,” said pulmonologist Guy A. Zimmerman, MD, who is associate chair of the Department of Internal Medicine at the University of Utah School of Medicine and was an independent reviewer of this study for Nature.

“The findings have direct clinical relevance and provide a rich group of questions for future studies of platelet genesis and megakaryocyte function in lung inflammation and other inflammatory conditions, bleeding and thrombotic disorders, and transplantation.”

Lab mouse

The lungs may play a previously unrecognized role in blood production, according to preclinical research published in Nature.

Researchers discovered large numbers of megakaryocytes in the lungs of mice and found these cells produced roughly half of the animals’ platelets.

The team also identified a pool of hematopoietic progenitors in the extravascular spaces of mouse lungs that were capable of multi-lineage bone marrow reconstitution.

“This finding definitely suggests a more sophisticated view of the lungs—that they’re not just for respiration but also a key partner in formation of crucial aspects of the blood,” said study author Mark R. Looney, MD, of the University of California - San Francisco.

“What we’ve observed here in mice strongly suggests the lung may play a key role in blood formation in humans as well.”

The researchers believe these findings could have major implications for understanding diseases in which patients suffer from thrombocytopenia.

Imaging reveals surprise

This research was made possible by a refinement of a technique known as 2-photon intravital imaging. This approach allowed the researchers to visualize the behavior of individual cells within the blood vessels of a living mouse lung.

Dr Looney and his colleagues used the technique to examine interactions between the immune system and circulating platelets in the lungs in a mouse strain engineered so that platelets emit bright green fluorescence (GFP+).

In this way, the team noticed a large population of megakaryocytes in the lung vasculature. Though megakaryocytes had been observed in the lung before, they were generally thought to live and produce platelets primarily in the bone marrow.

“When we discovered this massive population of megakaryocytes that appeared to be living in the lung, we realized we had to follow this up,” said study author Emma Lefrançais, PhD, a postdoctoral researcher in Dr Looney’s lab.

More detailed imaging sessions revealed megakaryocytes in the act of producing more than 10 million platelets per hour within the lung vasculature. This suggests that roughly half of a mouse’s total platelet production occurs in the lung, not the bone marrow, as researchers had long presumed.

Subsequent experiments also revealed a variety of previously overlooked hematopoietic progenitors outside the lung vasculature.

Transplants provide more insight

The discovery of megakaryocytes and hematopoietic progenitors in the lung raised questions about how these cells move back and forth between the lung and bone marrow. To address these questions, the researchers conducted a set of lung transplant studies.

The team transplanted lungs from wild-type mice into mice with GFP+ megakaryocytes and vice-versa. The researchers said they observed proplatelet formation from GFP+ megakaryocytes in the lung vasculature of the GFP+ mice but not in the wild-type mice.

This suggests the megakaryocytes releasing platelets in the lung circulation originate from outside the lungs, the researchers said. And subsequent experiments suggested the megakaryocytes originate in the bone marrow.

“It’s fascinating that megakaryocytes travel all the way from the bone marrow to the lungs to produce platelets,” said Guadalupe Ortiz-Muñoz, PhD, a postdoctoral researcher in Dr Looney’s lab.

“It’s possible that the lung is an ideal bioreactor for platelet production because of the mechanical force of the blood, or perhaps because of some molecular signaling we don’t yet know about.”

In another experiment, the researchers transplanted lungs with GFP+ megakaryocyte progenitors into mutant mice with low platelet counts.

The transplants successfully restored platelet levels to normal, an effect that persisted over a few months of observation—much longer than the lifespan of individual megakaryocytes or platelets.

To the researchers, this indicated that resident megakaryocyte progenitors in the transplanted lungs had become activated by the recipient mouse’s low platelet counts and had produced healthy megakaryocytes to restore proper platelet production.

Finally, the researchers tested whether lung hematopoietic progenitors were capable of multi-lineage bone marrow reconstitution.

They found that cells originating from transplanted lungs traveled to damaged bone marrow and contributed to the production of platelets and other blood cells, including neutrophils, B cells, and T cells.

The researchers said these experiments suggest the lungs play host to a variety of hematopoietic progenitors capable of reconstituting damaged bone marrow and restoring the production of many components of the blood.

“To our knowledge, this is the first description of blood progenitors resident in the lung, and it raises a lot of questions with clinical relevance for the millions of people who suffer from thrombocytopenia,” Dr Looney said.

In particular, the study suggests that researchers who have proposed treating platelet diseases with platelets produced from engineered megakaryocytes should look to the lungs as a resource for platelet production, Dr Looney noted.

The study also presents new avenues of research for stem cell biologists to explore how the bone marrow and lung collaborate to produce a healthy blood system through the mutual exchange of stem cells.

“These observations alter existing paradigms regarding blood cell formation, lung biology and disease, and transplantation,” said pulmonologist Guy A. Zimmerman, MD, who is associate chair of the Department of Internal Medicine at the University of Utah School of Medicine and was an independent reviewer of this study for Nature.

“The findings have direct clinical relevance and provide a rich group of questions for future studies of platelet genesis and megakaryocyte function in lung inflammation and other inflammatory conditions, bleeding and thrombotic disorders, and transplantation.”

Lab mouse

The lungs may play a previously unrecognized role in blood production, according to preclinical research published in Nature.

Researchers discovered large numbers of megakaryocytes in the lungs of mice and found these cells produced roughly half of the animals’ platelets.

The team also identified a pool of hematopoietic progenitors in the extravascular spaces of mouse lungs that were capable of multi-lineage bone marrow reconstitution.

“This finding definitely suggests a more sophisticated view of the lungs—that they’re not just for respiration but also a key partner in formation of crucial aspects of the blood,” said study author Mark R. Looney, MD, of the University of California - San Francisco.

“What we’ve observed here in mice strongly suggests the lung may play a key role in blood formation in humans as well.”

The researchers believe these findings could have major implications for understanding diseases in which patients suffer from thrombocytopenia.

Imaging reveals surprise

This research was made possible by a refinement of a technique known as 2-photon intravital imaging. This approach allowed the researchers to visualize the behavior of individual cells within the blood vessels of a living mouse lung.

Dr Looney and his colleagues used the technique to examine interactions between the immune system and circulating platelets in the lungs in a mouse strain engineered so that platelets emit bright green fluorescence (GFP+).

In this way, the team noticed a large population of megakaryocytes in the lung vasculature. Though megakaryocytes had been observed in the lung before, they were generally thought to live and produce platelets primarily in the bone marrow.

“When we discovered this massive population of megakaryocytes that appeared to be living in the lung, we realized we had to follow this up,” said study author Emma Lefrançais, PhD, a postdoctoral researcher in Dr Looney’s lab.

More detailed imaging sessions revealed megakaryocytes in the act of producing more than 10 million platelets per hour within the lung vasculature. This suggests that roughly half of a mouse’s total platelet production occurs in the lung, not the bone marrow, as researchers had long presumed.

Subsequent experiments also revealed a variety of previously overlooked hematopoietic progenitors outside the lung vasculature.

Transplants provide more insight

The discovery of megakaryocytes and hematopoietic progenitors in the lung raised questions about how these cells move back and forth between the lung and bone marrow. To address these questions, the researchers conducted a set of lung transplant studies.

The team transplanted lungs from wild-type mice into mice with GFP+ megakaryocytes and vice-versa. The researchers said they observed proplatelet formation from GFP+ megakaryocytes in the lung vasculature of the GFP+ mice but not in the wild-type mice.

This suggests the megakaryocytes releasing platelets in the lung circulation originate from outside the lungs, the researchers said. And subsequent experiments suggested the megakaryocytes originate in the bone marrow.

“It’s fascinating that megakaryocytes travel all the way from the bone marrow to the lungs to produce platelets,” said Guadalupe Ortiz-Muñoz, PhD, a postdoctoral researcher in Dr Looney’s lab.

“It’s possible that the lung is an ideal bioreactor for platelet production because of the mechanical force of the blood, or perhaps because of some molecular signaling we don’t yet know about.”

In another experiment, the researchers transplanted lungs with GFP+ megakaryocyte progenitors into mutant mice with low platelet counts.

The transplants successfully restored platelet levels to normal, an effect that persisted over a few months of observation—much longer than the lifespan of individual megakaryocytes or platelets.

To the researchers, this indicated that resident megakaryocyte progenitors in the transplanted lungs had become activated by the recipient mouse’s low platelet counts and had produced healthy megakaryocytes to restore proper platelet production.

Finally, the researchers tested whether lung hematopoietic progenitors were capable of multi-lineage bone marrow reconstitution.

They found that cells originating from transplanted lungs traveled to damaged bone marrow and contributed to the production of platelets and other blood cells, including neutrophils, B cells, and T cells.

The researchers said these experiments suggest the lungs play host to a variety of hematopoietic progenitors capable of reconstituting damaged bone marrow and restoring the production of many components of the blood.

“To our knowledge, this is the first description of blood progenitors resident in the lung, and it raises a lot of questions with clinical relevance for the millions of people who suffer from thrombocytopenia,” Dr Looney said.

In particular, the study suggests that researchers who have proposed treating platelet diseases with platelets produced from engineered megakaryocytes should look to the lungs as a resource for platelet production, Dr Looney noted.

The study also presents new avenues of research for stem cell biologists to explore how the bone marrow and lung collaborate to produce a healthy blood system through the mutual exchange of stem cells.

“These observations alter existing paradigms regarding blood cell formation, lung biology and disease, and transplantation,” said pulmonologist Guy A. Zimmerman, MD, who is associate chair of the Department of Internal Medicine at the University of Utah School of Medicine and was an independent reviewer of this study for Nature.

“The findings have direct clinical relevance and provide a rich group of questions for future studies of platelet genesis and megakaryocyte function in lung inflammation and other inflammatory conditions, bleeding and thrombotic disorders, and transplantation.”

Photo from David Levy

Physicians have reported what they believe is the first case of an allogeneic hematopoietic stem cell transplant (allo-HSCT) curing an adult with congenital dyserythropoietic anemia (CDA).

The patient, David Levy, was previously transfusion-dependent and suffered from iron overload, severe pain, and other adverse effects of his illness.

Levy was denied a transplant for years, but, in 2014, he received a non-myeloablative allo-HSCT from a matched, unrelated donor.

Now, Levy no longer requires transfusions, iron chelation, or immunosuppression, and says he is able to live a normal life.

Damiano Rondelli, MD, of the University of Illinois at Chicago, and his colleagues described Levy’s case in a letter to Bone Marrow Transplantation.

Levy was diagnosed with CDA at 4 months of age and was treated with regular blood transfusions for most of his life. He was 24 when the pain from his illness became so severe that he had to withdraw from graduate school.

“I spent the following years doing nothing—no work, no school, no social contact—because all I could focus on was managing my pain and getting my health back on track,” Levy said.

By age 32, Levy required transfusions every 2 to 3 weeks, had undergone a splenectomy, had an enlarged liver, and was suffering from fatigue, heart palpitations, and iron overload.

“It was bad,” Levy said. “I had been through enough pain. I was angry and depressed, and I wanted a cure. That’s why I started emailing Dr Rondelli.”

Dr Rondelli said that because of Levy’s range of illnesses and inability to tolerate chemotherapy and radiation, several institutions had denied him the possibility of a transplant.

However, Dr Rondelli and his colleagues had reported success with chemotherapy-free allo-HSCT in patients with sickle cell disease. So Dr Rondelli performed Levy’s transplant in 2014.

Levy received a peripheral blood stem cell transplant from an unrelated donor who was a 10/10 HLA match but ABO incompatible. He received conditioning with rabbit anti-thymocyte globulin, fludarabine, cyclophosphamide, and total body irradiation.

Levy also received graft-vs-host disease (GVHD) prophylaxis consisting of high-dose cyclophosphamide, mycophenolate mofetil, and sirolimus. And he received standard antibacterial, antifungal, antiviral, and anti-Pneumocystis jiroveci prophylaxis.

Levy experienced platelet engraftment on day 20 and neutrophil engraftment on day 21. Whole-blood donor-cell chimerism was 98.7% on day 30 and 100% on day 60 and beyond.

Levy did develop transient hemolytic anemia due to the ABO incompatibility. He was given a total of 10 units of packed red blood cells until day 78.

Levy was tapered off all immunosuppression at 12 months and has shown no signs of acute or chronic GVHD.

At 24 months after HSCT, Levy’s hemoglobin was 13.7 g/dL, and his ferritin was 376 ng/mL. He has had no iron chelation since the transplant.

“The transplant was hard, and I had some complications, but I am back to normal now,” said Levy, who is now 35.

“I still have some pain and some lingering issues from the years my condition was not properly managed, but I can be independent now. That is the most important thing to me.”

Levy is finishing his doctorate in psychology and running group therapy sessions at a behavioral health hospital.

Dr Rondelli said the potential of this treatment approach is promising.

“The use of this transplant protocol may represent a safe therapeutic strategy to treat adult patients with many types of congenital anemias—perhaps the only possible cure,” he said.

“For many adult patients with a blood disorder, treatment options have been limited because they are often not sick enough to qualify for a risky procedure, or they are too sick to tolerate the toxic drugs used alongside a standard transplant. This procedure gives some adults the option of a stem cell transplant, which was not previously available.”

Photo from David Levy

Physicians have reported what they believe is the first case of an allogeneic hematopoietic stem cell transplant (allo-HSCT) curing an adult with congenital dyserythropoietic anemia (CDA).

The patient, David Levy, was previously transfusion-dependent and suffered from iron overload, severe pain, and other adverse effects of his illness.

Levy was denied a transplant for years, but, in 2014, he received a non-myeloablative allo-HSCT from a matched, unrelated donor.

Now, Levy no longer requires transfusions, iron chelation, or immunosuppression, and says he is able to live a normal life.

Damiano Rondelli, MD, of the University of Illinois at Chicago, and his colleagues described Levy’s case in a letter to Bone Marrow Transplantation.

Levy was diagnosed with CDA at 4 months of age and was treated with regular blood transfusions for most of his life. He was 24 when the pain from his illness became so severe that he had to withdraw from graduate school.

“I spent the following years doing nothing—no work, no school, no social contact—because all I could focus on was managing my pain and getting my health back on track,” Levy said.

By age 32, Levy required transfusions every 2 to 3 weeks, had undergone a splenectomy, had an enlarged liver, and was suffering from fatigue, heart palpitations, and iron overload.

“It was bad,” Levy said. “I had been through enough pain. I was angry and depressed, and I wanted a cure. That’s why I started emailing Dr Rondelli.”

Dr Rondelli said that because of Levy’s range of illnesses and inability to tolerate chemotherapy and radiation, several institutions had denied him the possibility of a transplant.

However, Dr Rondelli and his colleagues had reported success with chemotherapy-free allo-HSCT in patients with sickle cell disease. So Dr Rondelli performed Levy’s transplant in 2014.

Levy received a peripheral blood stem cell transplant from an unrelated donor who was a 10/10 HLA match but ABO incompatible. He received conditioning with rabbit anti-thymocyte globulin, fludarabine, cyclophosphamide, and total body irradiation.

Levy also received graft-vs-host disease (GVHD) prophylaxis consisting of high-dose cyclophosphamide, mycophenolate mofetil, and sirolimus. And he received standard antibacterial, antifungal, antiviral, and anti-Pneumocystis jiroveci prophylaxis.

Levy experienced platelet engraftment on day 20 and neutrophil engraftment on day 21. Whole-blood donor-cell chimerism was 98.7% on day 30 and 100% on day 60 and beyond.

Levy did develop transient hemolytic anemia due to the ABO incompatibility. He was given a total of 10 units of packed red blood cells until day 78.

Levy was tapered off all immunosuppression at 12 months and has shown no signs of acute or chronic GVHD.

At 24 months after HSCT, Levy’s hemoglobin was 13.7 g/dL, and his ferritin was 376 ng/mL. He has had no iron chelation since the transplant.

“The transplant was hard, and I had some complications, but I am back to normal now,” said Levy, who is now 35.

“I still have some pain and some lingering issues from the years my condition was not properly managed, but I can be independent now. That is the most important thing to me.”

Levy is finishing his doctorate in psychology and running group therapy sessions at a behavioral health hospital.

Dr Rondelli said the potential of this treatment approach is promising.

“The use of this transplant protocol may represent a safe therapeutic strategy to treat adult patients with many types of congenital anemias—perhaps the only possible cure,” he said.

“For many adult patients with a blood disorder, treatment options have been limited because they are often not sick enough to qualify for a risky procedure, or they are too sick to tolerate the toxic drugs used alongside a standard transplant. This procedure gives some adults the option of a stem cell transplant, which was not previously available.”

Photo from David Levy

Physicians have reported what they believe is the first case of an allogeneic hematopoietic stem cell transplant (allo-HSCT) curing an adult with congenital dyserythropoietic anemia (CDA).

The patient, David Levy, was previously transfusion-dependent and suffered from iron overload, severe pain, and other adverse effects of his illness.

Levy was denied a transplant for years, but, in 2014, he received a non-myeloablative allo-HSCT from a matched, unrelated donor.

Now, Levy no longer requires transfusions, iron chelation, or immunosuppression, and says he is able to live a normal life.

Damiano Rondelli, MD, of the University of Illinois at Chicago, and his colleagues described Levy’s case in a letter to Bone Marrow Transplantation.

Levy was diagnosed with CDA at 4 months of age and was treated with regular blood transfusions for most of his life. He was 24 when the pain from his illness became so severe that he had to withdraw from graduate school.

“I spent the following years doing nothing—no work, no school, no social contact—because all I could focus on was managing my pain and getting my health back on track,” Levy said.

By age 32, Levy required transfusions every 2 to 3 weeks, had undergone a splenectomy, had an enlarged liver, and was suffering from fatigue, heart palpitations, and iron overload.

“It was bad,” Levy said. “I had been through enough pain. I was angry and depressed, and I wanted a cure. That’s why I started emailing Dr Rondelli.”

Dr Rondelli said that because of Levy’s range of illnesses and inability to tolerate chemotherapy and radiation, several institutions had denied him the possibility of a transplant.

However, Dr Rondelli and his colleagues had reported success with chemotherapy-free allo-HSCT in patients with sickle cell disease. So Dr Rondelli performed Levy’s transplant in 2014.

Levy received a peripheral blood stem cell transplant from an unrelated donor who was a 10/10 HLA match but ABO incompatible. He received conditioning with rabbit anti-thymocyte globulin, fludarabine, cyclophosphamide, and total body irradiation.

Levy also received graft-vs-host disease (GVHD) prophylaxis consisting of high-dose cyclophosphamide, mycophenolate mofetil, and sirolimus. And he received standard antibacterial, antifungal, antiviral, and anti-Pneumocystis jiroveci prophylaxis.

Levy experienced platelet engraftment on day 20 and neutrophil engraftment on day 21. Whole-blood donor-cell chimerism was 98.7% on day 30 and 100% on day 60 and beyond.

Levy did develop transient hemolytic anemia due to the ABO incompatibility. He was given a total of 10 units of packed red blood cells until day 78.

Levy was tapered off all immunosuppression at 12 months and has shown no signs of acute or chronic GVHD.

At 24 months after HSCT, Levy’s hemoglobin was 13.7 g/dL, and his ferritin was 376 ng/mL. He has had no iron chelation since the transplant.

“The transplant was hard, and I had some complications, but I am back to normal now,” said Levy, who is now 35.

“I still have some pain and some lingering issues from the years my condition was not properly managed, but I can be independent now. That is the most important thing to me.”

Levy is finishing his doctorate in psychology and running group therapy sessions at a behavioral health hospital.

Dr Rondelli said the potential of this treatment approach is promising.

“The use of this transplant protocol may represent a safe therapeutic strategy to treat adult patients with many types of congenital anemias—perhaps the only possible cure,” he said.

“For many adult patients with a blood disorder, treatment options have been limited because they are often not sick enough to qualify for a risky procedure, or they are too sick to tolerate the toxic drugs used alongside a standard transplant. This procedure gives some adults the option of a stem cell transplant, which was not previously available.”

Image by Spencer Phillips

Black individuals with sickle cell trait (SCT) have an increased risk of developing end-stage renal disease (ESRD), according to new research.

The study indicates that having SCT actually doubles the risk of ESRD.

And the trait confers a similar degree of risk as APOL1 gene variants, which are currently the most widely recognized genetic contributors to kidney disease in blacks.

Researchers believe this finding may have important public policy implications for genetic counseling for individuals with SCT.

Rakhi P. Naik, MD, of Johns Hopkins University School of Medicine in Baltimore, Maryland, and her colleagues reported this finding in the Journal of the American Society of Nephrology.

Previous research suggested there is an association between SCT and chronic kidney disease, but it hasn’t been clear if that extends to ESRD. Studies have also suggested a possible association between kidney disease and hemoglobin C trait, but the link has not been confirmed.

So Dr Naik and her colleagues decided to investigate these potential links. To do so, the researchers analyzed data from a large, population-based study, the REasons for Geographic and Racial Differences in Stroke (REGARDS) study.

The team evaluated information on 9909 black individuals, 739 of whom had SCT and 243 of whom had hemoglobin C trait.

The data indicate that individuals with SCT have a 2-fold higher risk of developing ESRD when compared to those without SCT. But there is no association between hemoglobin C trait and ESRD.

At a median follow-up of 6.5 years, the incidence of ESRD was 5.4% (40/739) in participants with SCT, 2.5% (6/243) in subjects with hemoglobin C trait, and 2.6% (234/8927) in individuals without either trait.

The incidence rate for ESRD was 8.5 per 1000 person-years for participants with SCT, 3.9 per 1000 person-years for subjects with hemoglobin C trait, and 4.0 per 1000 person-years for individuals without either trait.

The researchers noted that SCT conferred a similar degree of ESRD risk as APOL1 gene variants. The hazard ratio for subjects with SCT was 2.03, and the hazard ratio for those with APOL1 high-risk genotypes was 1.77.

“Although you cannot change the genes you are born with, doctors can use this information to start screening for kidney disease earlier and to aggressively treat any other risk factors you may have, such as diabetes or high blood pressure,” Dr Naik said.

“We still need more studies to determine if there are other treatments that can be used to slow the progression of kidney disease, specifically in individuals with sickle cell trait.”

Image by Spencer Phillips

Black individuals with sickle cell trait (SCT) have an increased risk of developing end-stage renal disease (ESRD), according to new research.

The study indicates that having SCT actually doubles the risk of ESRD.

And the trait confers a similar degree of risk as APOL1 gene variants, which are currently the most widely recognized genetic contributors to kidney disease in blacks.

Researchers believe this finding may have important public policy implications for genetic counseling for individuals with SCT.

Rakhi P. Naik, MD, of Johns Hopkins University School of Medicine in Baltimore, Maryland, and her colleagues reported this finding in the Journal of the American Society of Nephrology.

Previous research suggested there is an association between SCT and chronic kidney disease, but it hasn’t been clear if that extends to ESRD. Studies have also suggested a possible association between kidney disease and hemoglobin C trait, but the link has not been confirmed.

So Dr Naik and her colleagues decided to investigate these potential links. To do so, the researchers analyzed data from a large, population-based study, the REasons for Geographic and Racial Differences in Stroke (REGARDS) study.

The team evaluated information on 9909 black individuals, 739 of whom had SCT and 243 of whom had hemoglobin C trait.

The data indicate that individuals with SCT have a 2-fold higher risk of developing ESRD when compared to those without SCT. But there is no association between hemoglobin C trait and ESRD.

At a median follow-up of 6.5 years, the incidence of ESRD was 5.4% (40/739) in participants with SCT, 2.5% (6/243) in subjects with hemoglobin C trait, and 2.6% (234/8927) in individuals without either trait.

The incidence rate for ESRD was 8.5 per 1000 person-years for participants with SCT, 3.9 per 1000 person-years for subjects with hemoglobin C trait, and 4.0 per 1000 person-years for individuals without either trait.

The researchers noted that SCT conferred a similar degree of ESRD risk as APOL1 gene variants. The hazard ratio for subjects with SCT was 2.03, and the hazard ratio for those with APOL1 high-risk genotypes was 1.77.

“Although you cannot change the genes you are born with, doctors can use this information to start screening for kidney disease earlier and to aggressively treat any other risk factors you may have, such as diabetes or high blood pressure,” Dr Naik said.

“We still need more studies to determine if there are other treatments that can be used to slow the progression of kidney disease, specifically in individuals with sickle cell trait.”

Image by Spencer Phillips

Black individuals with sickle cell trait (SCT) have an increased risk of developing end-stage renal disease (ESRD), according to new research.

The study indicates that having SCT actually doubles the risk of ESRD.

And the trait confers a similar degree of risk as APOL1 gene variants, which are currently the most widely recognized genetic contributors to kidney disease in blacks.

Researchers believe this finding may have important public policy implications for genetic counseling for individuals with SCT.

Rakhi P. Naik, MD, of Johns Hopkins University School of Medicine in Baltimore, Maryland, and her colleagues reported this finding in the Journal of the American Society of Nephrology.

Previous research suggested there is an association between SCT and chronic kidney disease, but it hasn’t been clear if that extends to ESRD. Studies have also suggested a possible association between kidney disease and hemoglobin C trait, but the link has not been confirmed.

So Dr Naik and her colleagues decided to investigate these potential links. To do so, the researchers analyzed data from a large, population-based study, the REasons for Geographic and Racial Differences in Stroke (REGARDS) study.

The team evaluated information on 9909 black individuals, 739 of whom had SCT and 243 of whom had hemoglobin C trait.

The data indicate that individuals with SCT have a 2-fold higher risk of developing ESRD when compared to those without SCT. But there is no association between hemoglobin C trait and ESRD.

At a median follow-up of 6.5 years, the incidence of ESRD was 5.4% (40/739) in participants with SCT, 2.5% (6/243) in subjects with hemoglobin C trait, and 2.6% (234/8927) in individuals without either trait.

The incidence rate for ESRD was 8.5 per 1000 person-years for participants with SCT, 3.9 per 1000 person-years for subjects with hemoglobin C trait, and 4.0 per 1000 person-years for individuals without either trait.

The researchers noted that SCT conferred a similar degree of ESRD risk as APOL1 gene variants. The hazard ratio for subjects with SCT was 2.03, and the hazard ratio for those with APOL1 high-risk genotypes was 1.77.

“Although you cannot change the genes you are born with, doctors can use this information to start screening for kidney disease earlier and to aggressively treat any other risk factors you may have, such as diabetes or high blood pressure,” Dr Naik said.

“We still need more studies to determine if there are other treatments that can be used to slow the progression of kidney disease, specifically in individuals with sickle cell trait.”

Photo by Linda Bartlett

The US Food and Drug Administration (FDA) has granted orphan drug designation for BI 836858, an anti-CD33 monoclonal antibody (mAb), in the treatment of myelodysplastic syndromes (MDS).

BI 836858 previously received orphan designation for the treatment of acute myeloid leukemia (AML).

The FDA grants orphan designation to drugs and biologics intended to treat, diagnose, or prevent rare diseases/disorders affecting fewer than 200,000 people in the US.

Orphan designation provides companies with certain incentives to develop products for rare diseases.

This includes a 50% tax break on research and development, a fee waiver, access to federal grants, and 7 years of market exclusivity if the product is approved.

About BI 836858

BI 836858 is a fully human, immunoglobulin G1 anti-CD33 mAb. It has been engineered for improved binding to FcgRIIIa to mediate natural killer cell antibody-dependent cellular cytotoxicity against CD33-expressing tumor cells.

BI 836858 is being developed by Boehringer Ingelheim.

A phase 1/2 trial (NCT02240706) of BI 836858 in patients with MDS is ongoing. The phase 1 portion was designed to evaluate various doses of the mAb in patients with low or intermediate-1 risk MDS with symptomatic anemia.

The phase 2 portion was designed to compare BI 836858 plus best supportive care to best supportive care alone in patients with low- or intermediate-1-risk MDS who have symptomatic anemia but do not have a 5q deletion.

BI 836858 is also being tested in combination with decitabine in a phase 1/2 study (NCT02632721) of patients with AML.

The goals of the phase 1 portion and the phase 1 extension are to determine the maximum-tolerated dose/recommended dose, safety, pharmacokinetics, and efficacy of BI 836858 in combination with decitabine.

The goals of the phase 2 portion of the study are to investigate the efficacy, safety, and pharmacokinetics of BI 836858 in combination with decitabine compared to decitabine monotherapy.

BI 836858 was previously evaluated in combination with decitabine in a preclinical study. The combination exhibited activity against AML in vitro. The research was published in Blood last year.

BI 836858 is also being evaluated as part of the Leukemia & Lymphoma Society’s Beat AML Master Trial program to advance treatment for patients with AML.

In this trial, investigators are using genomic technology to identify AML mutations in newly diagnosed patients over the age of 60 and match the patients with an investigational drug or drugs best suited to attack the mutations found.

Photo by Linda Bartlett

The US Food and Drug Administration (FDA) has granted orphan drug designation for BI 836858, an anti-CD33 monoclonal antibody (mAb), in the treatment of myelodysplastic syndromes (MDS).

BI 836858 previously received orphan designation for the treatment of acute myeloid leukemia (AML).

The FDA grants orphan designation to drugs and biologics intended to treat, diagnose, or prevent rare diseases/disorders affecting fewer than 200,000 people in the US.

Orphan designation provides companies with certain incentives to develop products for rare diseases.

This includes a 50% tax break on research and development, a fee waiver, access to federal grants, and 7 years of market exclusivity if the product is approved.

About BI 836858

BI 836858 is a fully human, immunoglobulin G1 anti-CD33 mAb. It has been engineered for improved binding to FcgRIIIa to mediate natural killer cell antibody-dependent cellular cytotoxicity against CD33-expressing tumor cells.

BI 836858 is being developed by Boehringer Ingelheim.

A phase 1/2 trial (NCT02240706) of BI 836858 in patients with MDS is ongoing. The phase 1 portion was designed to evaluate various doses of the mAb in patients with low or intermediate-1 risk MDS with symptomatic anemia.

The phase 2 portion was designed to compare BI 836858 plus best supportive care to best supportive care alone in patients with low- or intermediate-1-risk MDS who have symptomatic anemia but do not have a 5q deletion.

BI 836858 is also being tested in combination with decitabine in a phase 1/2 study (NCT02632721) of patients with AML.

The goals of the phase 1 portion and the phase 1 extension are to determine the maximum-tolerated dose/recommended dose, safety, pharmacokinetics, and efficacy of BI 836858 in combination with decitabine.

The goals of the phase 2 portion of the study are to investigate the efficacy, safety, and pharmacokinetics of BI 836858 in combination with decitabine compared to decitabine monotherapy.

BI 836858 was previously evaluated in combination with decitabine in a preclinical study. The combination exhibited activity against AML in vitro. The research was published in Blood last year.

BI 836858 is also being evaluated as part of the Leukemia & Lymphoma Society’s Beat AML Master Trial program to advance treatment for patients with AML.

In this trial, investigators are using genomic technology to identify AML mutations in newly diagnosed patients over the age of 60 and match the patients with an investigational drug or drugs best suited to attack the mutations found.

Photo by Linda Bartlett

The US Food and Drug Administration (FDA) has granted orphan drug designation for BI 836858, an anti-CD33 monoclonal antibody (mAb), in the treatment of myelodysplastic syndromes (MDS).

BI 836858 previously received orphan designation for the treatment of acute myeloid leukemia (AML).

The FDA grants orphan designation to drugs and biologics intended to treat, diagnose, or prevent rare diseases/disorders affecting fewer than 200,000 people in the US.

Orphan designation provides companies with certain incentives to develop products for rare diseases.

This includes a 50% tax break on research and development, a fee waiver, access to federal grants, and 7 years of market exclusivity if the product is approved.

About BI 836858

BI 836858 is a fully human, immunoglobulin G1 anti-CD33 mAb. It has been engineered for improved binding to FcgRIIIa to mediate natural killer cell antibody-dependent cellular cytotoxicity against CD33-expressing tumor cells.

BI 836858 is being developed by Boehringer Ingelheim.

A phase 1/2 trial (NCT02240706) of BI 836858 in patients with MDS is ongoing. The phase 1 portion was designed to evaluate various doses of the mAb in patients with low or intermediate-1 risk MDS with symptomatic anemia.

The phase 2 portion was designed to compare BI 836858 plus best supportive care to best supportive care alone in patients with low- or intermediate-1-risk MDS who have symptomatic anemia but do not have a 5q deletion.

BI 836858 is also being tested in combination with decitabine in a phase 1/2 study (NCT02632721) of patients with AML.

The goals of the phase 1 portion and the phase 1 extension are to determine the maximum-tolerated dose/recommended dose, safety, pharmacokinetics, and efficacy of BI 836858 in combination with decitabine.

The goals of the phase 2 portion of the study are to investigate the efficacy, safety, and pharmacokinetics of BI 836858 in combination with decitabine compared to decitabine monotherapy.

BI 836858 was previously evaluated in combination with decitabine in a preclinical study. The combination exhibited activity against AML in vitro. The research was published in Blood last year.

BI 836858 is also being evaluated as part of the Leukemia & Lymphoma Society’s Beat AML Master Trial program to advance treatment for patients with AML.

In this trial, investigators are using genomic technology to identify AML mutations in newly diagnosed patients over the age of 60 and match the patients with an investigational drug or drugs best suited to attack the mutations found.

Image by Betty Pace

Researchers have reported a favorable outcome in the first patient with severe sickle cell disease (SCD) to receive gene therapy in the HGB-205 study.

The subject, known as Patient 1204, was treated with LentiGlobin BB305, a product consisting of his own manipulated hematopoietic stem cells (HSCs).

A functional human β-globin gene was inserted into the patient’s HSCs ex vivo, and the cells were returned to him via transplant.

Fifteen months after receiving this treatment, Patient 1204 had high levels of anti-sickling hemoglobin (HbA^T87Q), and there were no adverse events thought to be related to LentiGlobin BB305.

These results were published in NEJM. The research was supported by bluebird bio, the company developing LentiGlobin BB305.

Patient 1204 is a male with βS/βS genotype. In May 2014, at 13 years of age, the patient was enrolled in the HGB-205 study at Hôpital Necker-Enfants Malades in Paris, France.

The patient had received hydroxyurea from age 2 to 9 and had both a cholecystectomy and a splenectomy. He received regular transfusions (plus iron chelation with deferasirox) for 4 years prior to this study.

The patient had an average of 1.6 SCD-related events annually in the 9 years prior to starting transfusions. His complications from SCD included vaso-occlusive crises, acute-chest syndrome, bilateral hip osteonecrosis, and cerebral vasculopathy.

The patient underwent 2 bone marrow harvests to collect HSCs for gene transfer and back-up (6.2×10⁸ and 5.4×10⁸ total nucleated cells/kg harvested).

CD34+ cells were enriched from the harvested marrow and then transduced with LentiGlobin BB305 lentiviral vector.

The patient underwent myeloablation with intravenous busulfan (2.3 to 4.8 mg/kg per day for 4 days) with daily pharmacokinetic studies and dose adjustment. Total busulfan area under the curve was 19,363 μmol/min.

After a 2-day washout, the patient received LentiGlobin BB305 in October 2014 at a post-thaw total dose of 5.6×10⁶ CD34+ cells/kg. Neutrophil and platelet engraftment were achieved on day 38 and day 91 post-transplant, respectively.

Red blood cell transfusions were to be continued after transplant until a sufficient proportion of HbA^T87Q (25% to 30% of total hemoglobin) was detected. Transfusions were discontinued after day 88 post-transplant.

HbA^T87Q reached 5.5 g/dL (46% of total hemoglobin) at month 9 and continued to increase to 5.7 g/dL at month 15 (48%). Hemoglobin S levels were 5.5 g/dL (46%) at month 9 and 5.8 g/dL (49%) at month 15.

Total hemoglobin levels were stable, between 10.6 and 12.0 g/dL, from months 6 to 15. Fetal hemoglobin levels remained below 1.0 g/dL.

No adverse events related to LentiGlobin BB305 were reported. There were, however, adverse events related to busulfan conditioning (grade 3 anemia, thrombocytopenia, and infection; grade 4 neutropenia).

During 15 months of follow-up, there were no SCD-related clinical events or hospitalizations. The patient was able to stop all medications, including pain medication.

The patient resumed regular school attendance and reported full participation in normal physical activities.

“We have managed this patient at Necker for more than 10 years, and standard treatments were not able to control his SCD symptoms,” said Marina Cavazzana, MD, PhD, of Hôpital Necker-Enfants Malades.

“He had to receive blood transfusions every month to prevent severe pain crises. Since receiving the autologous stem cell transplant with LentiGlobin, he has been free from severe symptoms and has resumed normal activities, without the need for further transfusions.”

Image by Betty Pace

Researchers have reported a favorable outcome in the first patient with severe sickle cell disease (SCD) to receive gene therapy in the HGB-205 study.

The subject, known as Patient 1204, was treated with LentiGlobin BB305, a product consisting of his own manipulated hematopoietic stem cells (HSCs).

A functional human β-globin gene was inserted into the patient’s HSCs ex vivo, and the cells were returned to him via transplant.

Fifteen months after receiving this treatment, Patient 1204 had high levels of anti-sickling hemoglobin (HbA^T87Q), and there were no adverse events thought to be related to LentiGlobin BB305.

These results were published in NEJM. The research was supported by bluebird bio, the company developing LentiGlobin BB305.

Patient 1204 is a male with βS/βS genotype. In May 2014, at 13 years of age, the patient was enrolled in the HGB-205 study at Hôpital Necker-Enfants Malades in Paris, France.

The patient had received hydroxyurea from age 2 to 9 and had both a cholecystectomy and a splenectomy. He received regular transfusions (plus iron chelation with deferasirox) for 4 years prior to this study.

The patient had an average of 1.6 SCD-related events annually in the 9 years prior to starting transfusions. His complications from SCD included vaso-occlusive crises, acute-chest syndrome, bilateral hip osteonecrosis, and cerebral vasculopathy.

The patient underwent 2 bone marrow harvests to collect HSCs for gene transfer and back-up (6.2×10⁸ and 5.4×10⁸ total nucleated cells/kg harvested).

CD34+ cells were enriched from the harvested marrow and then transduced with LentiGlobin BB305 lentiviral vector.

The patient underwent myeloablation with intravenous busulfan (2.3 to 4.8 mg/kg per day for 4 days) with daily pharmacokinetic studies and dose adjustment. Total busulfan area under the curve was 19,363 μmol/min.

After a 2-day washout, the patient received LentiGlobin BB305 in October 2014 at a post-thaw total dose of 5.6×10⁶ CD34+ cells/kg. Neutrophil and platelet engraftment were achieved on day 38 and day 91 post-transplant, respectively.

Red blood cell transfusions were to be continued after transplant until a sufficient proportion of HbA^T87Q (25% to 30% of total hemoglobin) was detected. Transfusions were discontinued after day 88 post-transplant.

HbA^T87Q reached 5.5 g/dL (46% of total hemoglobin) at month 9 and continued to increase to 5.7 g/dL at month 15 (48%). Hemoglobin S levels were 5.5 g/dL (46%) at month 9 and 5.8 g/dL (49%) at month 15.

Total hemoglobin levels were stable, between 10.6 and 12.0 g/dL, from months 6 to 15. Fetal hemoglobin levels remained below 1.0 g/dL.

No adverse events related to LentiGlobin BB305 were reported. There were, however, adverse events related to busulfan conditioning (grade 3 anemia, thrombocytopenia, and infection; grade 4 neutropenia).

During 15 months of follow-up, there were no SCD-related clinical events or hospitalizations. The patient was able to stop all medications, including pain medication.

The patient resumed regular school attendance and reported full participation in normal physical activities.

“We have managed this patient at Necker for more than 10 years, and standard treatments were not able to control his SCD symptoms,” said Marina Cavazzana, MD, PhD, of Hôpital Necker-Enfants Malades.

“He had to receive blood transfusions every month to prevent severe pain crises. Since receiving the autologous stem cell transplant with LentiGlobin, he has been free from severe symptoms and has resumed normal activities, without the need for further transfusions.”

Image by Betty Pace

Researchers have reported a favorable outcome in the first patient with severe sickle cell disease (SCD) to receive gene therapy in the HGB-205 study.

The subject, known as Patient 1204, was treated with LentiGlobin BB305, a product consisting of his own manipulated hematopoietic stem cells (HSCs).

A functional human β-globin gene was inserted into the patient’s HSCs ex vivo, and the cells were returned to him via transplant.

Fifteen months after receiving this treatment, Patient 1204 had high levels of anti-sickling hemoglobin (HbA^T87Q), and there were no adverse events thought to be related to LentiGlobin BB305.

These results were published in NEJM. The research was supported by bluebird bio, the company developing LentiGlobin BB305.

Patient 1204 is a male with βS/βS genotype. In May 2014, at 13 years of age, the patient was enrolled in the HGB-205 study at Hôpital Necker-Enfants Malades in Paris, France.

The patient had received hydroxyurea from age 2 to 9 and had both a cholecystectomy and a splenectomy. He received regular transfusions (plus iron chelation with deferasirox) for 4 years prior to this study.

The patient had an average of 1.6 SCD-related events annually in the 9 years prior to starting transfusions. His complications from SCD included vaso-occlusive crises, acute-chest syndrome, bilateral hip osteonecrosis, and cerebral vasculopathy.

The patient underwent 2 bone marrow harvests to collect HSCs for gene transfer and back-up (6.2×10⁸ and 5.4×10⁸ total nucleated cells/kg harvested).

CD34+ cells were enriched from the harvested marrow and then transduced with LentiGlobin BB305 lentiviral vector.

The patient underwent myeloablation with intravenous busulfan (2.3 to 4.8 mg/kg per day for 4 days) with daily pharmacokinetic studies and dose adjustment. Total busulfan area under the curve was 19,363 μmol/min.

After a 2-day washout, the patient received LentiGlobin BB305 in October 2014 at a post-thaw total dose of 5.6×10⁶ CD34+ cells/kg. Neutrophil and platelet engraftment were achieved on day 38 and day 91 post-transplant, respectively.

Red blood cell transfusions were to be continued after transplant until a sufficient proportion of HbA^T87Q (25% to 30% of total hemoglobin) was detected. Transfusions were discontinued after day 88 post-transplant.

HbA^T87Q reached 5.5 g/dL (46% of total hemoglobin) at month 9 and continued to increase to 5.7 g/dL at month 15 (48%). Hemoglobin S levels were 5.5 g/dL (46%) at month 9 and 5.8 g/dL (49%) at month 15.

Total hemoglobin levels were stable, between 10.6 and 12.0 g/dL, from months 6 to 15. Fetal hemoglobin levels remained below 1.0 g/dL.

No adverse events related to LentiGlobin BB305 were reported. There were, however, adverse events related to busulfan conditioning (grade 3 anemia, thrombocytopenia, and infection; grade 4 neutropenia).

During 15 months of follow-up, there were no SCD-related clinical events or hospitalizations. The patient was able to stop all medications, including pain medication.

The patient resumed regular school attendance and reported full participation in normal physical activities.

“We have managed this patient at Necker for more than 10 years, and standard treatments were not able to control his SCD symptoms,” said Marina Cavazzana, MD, PhD, of Hôpital Necker-Enfants Malades.

“He had to receive blood transfusions every month to prevent severe pain crises. Since receiving the autologous stem cell transplant with LentiGlobin, he has been free from severe symptoms and has resumed normal activities, without the need for further transfusions.”

A teenage boy with sickle cell disease has been successfully treated with a therapy that uses a viral vector to insert functional genes into blood-producing stem cells.

The patient’s positive response to the intervention was first reported in 2015, and his clinical remission was reported in late 2016 at the American Society of Hematology’s annual meeting.

The new report, published online March 1 in the New England Journal of Medicine, contains the first detailed description of the case (2017;376:848-55).

Dr_Microbe/Thinkstock

A teenage boy with sickle cell disease has been successfully treated with a therapy that uses a viral vector to insert functional genes into blood-producing stem cells.

The patient’s positive response to the intervention was first reported in 2015, and his clinical remission was reported in late 2016 at the American Society of Hematology’s annual meeting.

The new report, published online March 1 in the New England Journal of Medicine, contains the first detailed description of the case (2017;376:848-55).

Dr_Microbe/Thinkstock

A teenage boy with sickle cell disease has been successfully treated with a therapy that uses a viral vector to insert functional genes into blood-producing stem cells.

The patient’s positive response to the intervention was first reported in 2015, and his clinical remission was reported in late 2016 at the American Society of Hematology’s annual meeting.

The new report, published online March 1 in the New England Journal of Medicine, contains the first detailed description of the case (2017;376:848-55).

Dr_Microbe/Thinkstock

Patients with beta thalassemia major who were chelated only with oral deferasirox experienced significant improvements in liver stiffness, both from baseline and compared with patients who interrupted deferasirox therapy because of pregnancy, according to a small prospective 5-year study.

Transient elastography showed that continuous therapy with deferasirox (median dose, 35 mg per kg) yielded an 0.85 kPa average improvement in liver stiffness compared with baseline (P = .02), reported Nikolaos Sousos of Aristotle University of Thessaloniki, Greece, and his associates (Br J Haematol. 2017 Jan 20. doi: 10.1111/bjh.14509).

In contrast, interrupting therapy for a median of 16 months because of successful pregnancy led to an average increase in liver stiffness of 1.84 kPa – a significant difference between groups (P = .005) even after the researchers controlled for gender, age, ferritin levels, and T2-weighted magnetic resonance imaging (MRI) measurements of iron deposition in the liver and heart.

Patients with beta thalassemia major often develop liver fibrosis because of excessive intestinal iron absorption, iron overload from transfusions, or hepatitis C virus infection, the investigators noted. The median age of the patients in this study was 32 years (range, 20-47 years), they were HCV negative, and they received regular transfusions to maintain hemoglobin levels above 95 g/L. The seven female participants who temporarily stopped deferasirox because of pregnancy all restarted therapy at least 8 months before their follow-up transient elastography liver stiffness measurement, the investigators reported.

T2-weighted MRI measurements of liver iron concentration also had improved at follow-up, reflecting “better control of iron overload,” although the difference from baseline was not statistically significant, the investigators noted. This result reinforces previous findings (Gastroenterology. 2011;141[4]:1202-11) that long-term deferasirox therapy can significantly improve liver fibrosis in patients with beta thalassemia, regardless of liver iron concentration, the researchers added. Together, those findings suggest that “improvement in liver fibrosis, rather than liver iron concentration should be the primary effect of chelation therapy,” they suggested.

The Research Committee of Aristotle University of Thessaloniki, Novartis Hellas (Novartis AG, Basel, Switzerland), and the Greek Thalassaemia Association funded the study. The authors declared having no competing interests.

Patients with beta thalassemia major who were chelated only with oral deferasirox experienced significant improvements in liver stiffness, both from baseline and compared with patients who interrupted deferasirox therapy because of pregnancy, according to a small prospective 5-year study.

Transient elastography showed that continuous therapy with deferasirox (median dose, 35 mg per kg) yielded an 0.85 kPa average improvement in liver stiffness compared with baseline (P = .02), reported Nikolaos Sousos of Aristotle University of Thessaloniki, Greece, and his associates (Br J Haematol. 2017 Jan 20. doi: 10.1111/bjh.14509).

In contrast, interrupting therapy for a median of 16 months because of successful pregnancy led to an average increase in liver stiffness of 1.84 kPa – a significant difference between groups (P = .005) even after the researchers controlled for gender, age, ferritin levels, and T2-weighted magnetic resonance imaging (MRI) measurements of iron deposition in the liver and heart.

Patients with beta thalassemia major often develop liver fibrosis because of excessive intestinal iron absorption, iron overload from transfusions, or hepatitis C virus infection, the investigators noted. The median age of the patients in this study was 32 years (range, 20-47 years), they were HCV negative, and they received regular transfusions to maintain hemoglobin levels above 95 g/L. The seven female participants who temporarily stopped deferasirox because of pregnancy all restarted therapy at least 8 months before their follow-up transient elastography liver stiffness measurement, the investigators reported.

T2-weighted MRI measurements of liver iron concentration also had improved at follow-up, reflecting “better control of iron overload,” although the difference from baseline was not statistically significant, the investigators noted. This result reinforces previous findings (Gastroenterology. 2011;141[4]:1202-11) that long-term deferasirox therapy can significantly improve liver fibrosis in patients with beta thalassemia, regardless of liver iron concentration, the researchers added. Together, those findings suggest that “improvement in liver fibrosis, rather than liver iron concentration should be the primary effect of chelation therapy,” they suggested.

The Research Committee of Aristotle University of Thessaloniki, Novartis Hellas (Novartis AG, Basel, Switzerland), and the Greek Thalassaemia Association funded the study. The authors declared having no competing interests.

Patients with beta thalassemia major who were chelated only with oral deferasirox experienced significant improvements in liver stiffness, both from baseline and compared with patients who interrupted deferasirox therapy because of pregnancy, according to a small prospective 5-year study.

Transient elastography showed that continuous therapy with deferasirox (median dose, 35 mg per kg) yielded an 0.85 kPa average improvement in liver stiffness compared with baseline (P = .02), reported Nikolaos Sousos of Aristotle University of Thessaloniki, Greece, and his associates (Br J Haematol. 2017 Jan 20. doi: 10.1111/bjh.14509).

In contrast, interrupting therapy for a median of 16 months because of successful pregnancy led to an average increase in liver stiffness of 1.84 kPa – a significant difference between groups (P = .005) even after the researchers controlled for gender, age, ferritin levels, and T2-weighted magnetic resonance imaging (MRI) measurements of iron deposition in the liver and heart.

Patients with beta thalassemia major often develop liver fibrosis because of excessive intestinal iron absorption, iron overload from transfusions, or hepatitis C virus infection, the investigators noted. The median age of the patients in this study was 32 years (range, 20-47 years), they were HCV negative, and they received regular transfusions to maintain hemoglobin levels above 95 g/L. The seven female participants who temporarily stopped deferasirox because of pregnancy all restarted therapy at least 8 months before their follow-up transient elastography liver stiffness measurement, the investigators reported.

T2-weighted MRI measurements of liver iron concentration also had improved at follow-up, reflecting “better control of iron overload,” although the difference from baseline was not statistically significant, the investigators noted. This result reinforces previous findings (Gastroenterology. 2011;141[4]:1202-11) that long-term deferasirox therapy can significantly improve liver fibrosis in patients with beta thalassemia, regardless of liver iron concentration, the researchers added. Together, those findings suggest that “improvement in liver fibrosis, rather than liver iron concentration should be the primary effect of chelation therapy,” they suggested.

The Research Committee of Aristotle University of Thessaloniki, Novartis Hellas (Novartis AG, Basel, Switzerland), and the Greek Thalassaemia Association funded the study. The authors declared having no competing interests.

Among adults with sickle cell disease, early mortality is associated with increasing tricuspid regurgitant jet velocity on ECG, reticulocyte count, brain natriuretic peptide levels, and patient age, and with decreasing fetal hemoglobin levels, according to a report published in Haematologica.

Although survival improved among children with sickle cell disease (SCD) following the Food and Drug Administration approval of hydroxyurea treatment in 1998, mortality remains high among adult patients. To examine the clinical and laboratory factors underlying early mortality in this patient population, researchers combined the findings from their single-center cohort study of 161 clinic patients and a meta-analysis of nine studies in the literature, for a total of 3,257 participants. This is “the largest number of SCD patients in whom risk factors for mortality have been evaluated in the hydroxyurea era,” said Poulami Maitra, PhD, of the department of biostatistics at the University of North Carolina, Chapel Hill, and her associates.

The clinic cohort had a median age of 36 years (range, 18-71 years), and there were 29 deaths during a median follow-up of 7.2 years. The median age at death was 48 years. Similarly, the median age at death ranged from 39.7 to 53 years in the meta-analysis.

In the combined cohort, patients who had a tricuspid regurgitant jet velocity of 2.5 m/s or more had three times greater risk of dying than did patients who had lower values, and the risk of dying was approximately doubled for every 1-U elevation in log(N-terminal pro-B type natriuretic peptide), which reflects increasing ventricular strain. Both links have been reported before. The findings confirm that recent clinical practice guidelines recommending periodic echocardiographic screening for these patients is warranted, the investigators said (Haematologica. 2017 Jan 19. doi: 10.3324/haematol.2016.153791).

The hazard of dying was 5% higher for every 1% increase in reticulocyte count, which suggests that hemolysis contributes to early mortality in these patients. The hazard of dying also was 3% lower for every 1% increase in fetal hemoglobin. This association with fetal hemoglobin is the basis for the development of drugs that raise that level, such as hydroxyurea.

Mortality was 30% higher for every 10-year increase in patient age, reflecting the fact that people with SCD show increasing end-organ damage over time that contributes to their mortality, Dr. Maitra and her associates said.

This work was supported by the National Institutes of Health and the North Carolina Sickle Cell Program. Dr. Maitra reported having no relevant financial disclosures; one of her associates reported serving as a consultant to Pfizer and Global Blood Therapeutics.

Among adults with sickle cell disease, early mortality is associated with increasing tricuspid regurgitant jet velocity on ECG, reticulocyte count, brain natriuretic peptide levels, and patient age, and with decreasing fetal hemoglobin levels, according to a report published in Haematologica.

Although survival improved among children with sickle cell disease (SCD) following the Food and Drug Administration approval of hydroxyurea treatment in 1998, mortality remains high among adult patients. To examine the clinical and laboratory factors underlying early mortality in this patient population, researchers combined the findings from their single-center cohort study of 161 clinic patients and a meta-analysis of nine studies in the literature, for a total of 3,257 participants. This is “the largest number of SCD patients in whom risk factors for mortality have been evaluated in the hydroxyurea era,” said Poulami Maitra, PhD, of the department of biostatistics at the University of North Carolina, Chapel Hill, and her associates.

The clinic cohort had a median age of 36 years (range, 18-71 years), and there were 29 deaths during a median follow-up of 7.2 years. The median age at death was 48 years. Similarly, the median age at death ranged from 39.7 to 53 years in the meta-analysis.

In the combined cohort, patients who had a tricuspid regurgitant jet velocity of 2.5 m/s or more had three times greater risk of dying than did patients who had lower values, and the risk of dying was approximately doubled for every 1-U elevation in log(N-terminal pro-B type natriuretic peptide), which reflects increasing ventricular strain. Both links have been reported before. The findings confirm that recent clinical practice guidelines recommending periodic echocardiographic screening for these patients is warranted, the investigators said (Haematologica. 2017 Jan 19. doi: 10.3324/haematol.2016.153791).

The hazard of dying was 5% higher for every 1% increase in reticulocyte count, which suggests that hemolysis contributes to early mortality in these patients. The hazard of dying also was 3% lower for every 1% increase in fetal hemoglobin. This association with fetal hemoglobin is the basis for the development of drugs that raise that level, such as hydroxyurea.

Mortality was 30% higher for every 10-year increase in patient age, reflecting the fact that people with SCD show increasing end-organ damage over time that contributes to their mortality, Dr. Maitra and her associates said.

This work was supported by the National Institutes of Health and the North Carolina Sickle Cell Program. Dr. Maitra reported having no relevant financial disclosures; one of her associates reported serving as a consultant to Pfizer and Global Blood Therapeutics.

Among adults with sickle cell disease, early mortality is associated with increasing tricuspid regurgitant jet velocity on ECG, reticulocyte count, brain natriuretic peptide levels, and patient age, and with decreasing fetal hemoglobin levels, according to a report published in Haematologica.

Although survival improved among children with sickle cell disease (SCD) following the Food and Drug Administration approval of hydroxyurea treatment in 1998, mortality remains high among adult patients. To examine the clinical and laboratory factors underlying early mortality in this patient population, researchers combined the findings from their single-center cohort study of 161 clinic patients and a meta-analysis of nine studies in the literature, for a total of 3,257 participants. This is “the largest number of SCD patients in whom risk factors for mortality have been evaluated in the hydroxyurea era,” said Poulami Maitra, PhD, of the department of biostatistics at the University of North Carolina, Chapel Hill, and her associates.

The clinic cohort had a median age of 36 years (range, 18-71 years), and there were 29 deaths during a median follow-up of 7.2 years. The median age at death was 48 years. Similarly, the median age at death ranged from 39.7 to 53 years in the meta-analysis.

In the combined cohort, patients who had a tricuspid regurgitant jet velocity of 2.5 m/s or more had three times greater risk of dying than did patients who had lower values, and the risk of dying was approximately doubled for every 1-U elevation in log(N-terminal pro-B type natriuretic peptide), which reflects increasing ventricular strain. Both links have been reported before. The findings confirm that recent clinical practice guidelines recommending periodic echocardiographic screening for these patients is warranted, the investigators said (Haematologica. 2017 Jan 19. doi: 10.3324/haematol.2016.153791).

The hazard of dying was 5% higher for every 1% increase in reticulocyte count, which suggests that hemolysis contributes to early mortality in these patients. The hazard of dying also was 3% lower for every 1% increase in fetal hemoglobin. This association with fetal hemoglobin is the basis for the development of drugs that raise that level, such as hydroxyurea.

Mortality was 30% higher for every 10-year increase in patient age, reflecting the fact that people with SCD show increasing end-organ damage over time that contributes to their mortality, Dr. Maitra and her associates said.

This work was supported by the National Institutes of Health and the North Carolina Sickle Cell Program. Dr. Maitra reported having no relevant financial disclosures; one of her associates reported serving as a consultant to Pfizer and Global Blood Therapeutics.

Extended-release oxymorphone hydrochloride (Opana ER) tablets contain an inert ingredient that can trigger acute microangiopathic hemolytic anemia and thrombocytopenia in those who abuse the drug via intravenous injection, Ryan Hunt, of the Food and Drug Administration, and his colleagues reported.

High-molecular-weight polyethylene oxide appeared to be the cause of acute cases of thrombotic microangiopathy in three patients who were treated in the emergency department of a single hospital in Tennessee. All had chest pain, dyspnea, visual impairment, microangiopathic hemolytic anemia and thrombocytopenia, increased lactate dehydrogenase, and undetectable haptoglobin serum levels. Two patients also had acute renal failure. Plasma exchange therapy was initiated in all three; one required additional hemodialysis.

ADAMTS13 activity was normal in blood samples obtained in two patients before they started plasma exchange. Histologic evidence of thrombotic microangiopathy with endothelial swelling of arterioles and acute tubular injury without deposition of immune complexes was seen in kidney biopsies performed in two patients. In addition, gelatinous material occluded the dialysis catheter and apheresis tubings during the initial plasma exchange sessions, the researchers reported (Blood. 2017;129[7]:896-905).

To test the association of polyethylene oxide with thrombotic microangiopathy, the researchers heated a 40-mg Opana ER tablet cut in several pieces in a spoon with 2 mL water until boiling. They injected guinea pigs with 0.1 or 0.3 mg/kg of the extracted polyethylene oxide, either as a single dose or as five doses given at 1.5-hour intervals. A dose-dependent increase of polyethylene oxide in plasma peaked at 8 hours after the first dose was measured and paralleled with intravascular hemolysis with increased plasma concentration of free hemoglobin, schistocytes in the peripheral blood smear, and thrombocytopenia. Spiking control blood samples in vitro with polyethylene oxide did not result in hemolysis.

“Although injection abuse of prescription opioids is highly concentrated in certain regions of the United States, particularly in rural Appalachia, all physicians should be highly inquisitive of IV drug abuse when presented with cases of [thrombotic microangiopathy],” the researchers concluded.

The researchers had no relevant conflicts of interest. One of the researchers is employed by Quest Diagnostics.

mdales@frontlinemedcom.com

On Twitter @maryjodales

Extended-release oxymorphone hydrochloride (Opana ER) tablets contain an inert ingredient that can trigger acute microangiopathic hemolytic anemia and thrombocytopenia in those who abuse the drug via intravenous injection, Ryan Hunt, of the Food and Drug Administration, and his colleagues reported.

High-molecular-weight polyethylene oxide appeared to be the cause of acute cases of thrombotic microangiopathy in three patients who were treated in the emergency department of a single hospital in Tennessee. All had chest pain, dyspnea, visual impairment, microangiopathic hemolytic anemia and thrombocytopenia, increased lactate dehydrogenase, and undetectable haptoglobin serum levels. Two patients also had acute renal failure. Plasma exchange therapy was initiated in all three; one required additional hemodialysis.

ADAMTS13 activity was normal in blood samples obtained in two patients before they started plasma exchange. Histologic evidence of thrombotic microangiopathy with endothelial swelling of arterioles and acute tubular injury without deposition of immune complexes was seen in kidney biopsies performed in two patients. In addition, gelatinous material occluded the dialysis catheter and apheresis tubings during the initial plasma exchange sessions, the researchers reported (Blood. 2017;129[7]:896-905).

To test the association of polyethylene oxide with thrombotic microangiopathy, the researchers heated a 40-mg Opana ER tablet cut in several pieces in a spoon with 2 mL water until boiling. They injected guinea pigs with 0.1 or 0.3 mg/kg of the extracted polyethylene oxide, either as a single dose or as five doses given at 1.5-hour intervals. A dose-dependent increase of polyethylene oxide in plasma peaked at 8 hours after the first dose was measured and paralleled with intravascular hemolysis with increased plasma concentration of free hemoglobin, schistocytes in the peripheral blood smear, and thrombocytopenia. Spiking control blood samples in vitro with polyethylene oxide did not result in hemolysis.

“Although injection abuse of prescription opioids is highly concentrated in certain regions of the United States, particularly in rural Appalachia, all physicians should be highly inquisitive of IV drug abuse when presented with cases of [thrombotic microangiopathy],” the researchers concluded.

The researchers had no relevant conflicts of interest. One of the researchers is employed by Quest Diagnostics.

mdales@frontlinemedcom.com

On Twitter @maryjodales

Extended-release oxymorphone hydrochloride (Opana ER) tablets contain an inert ingredient that can trigger acute microangiopathic hemolytic anemia and thrombocytopenia in those who abuse the drug via intravenous injection, Ryan Hunt, of the Food and Drug Administration, and his colleagues reported.

High-molecular-weight polyethylene oxide appeared to be the cause of acute cases of thrombotic microangiopathy in three patients who were treated in the emergency department of a single hospital in Tennessee. All had chest pain, dyspnea, visual impairment, microangiopathic hemolytic anemia and thrombocytopenia, increased lactate dehydrogenase, and undetectable haptoglobin serum levels. Two patients also had acute renal failure. Plasma exchange therapy was initiated in all three; one required additional hemodialysis.

ADAMTS13 activity was normal in blood samples obtained in two patients before they started plasma exchange. Histologic evidence of thrombotic microangiopathy with endothelial swelling of arterioles and acute tubular injury without deposition of immune complexes was seen in kidney biopsies performed in two patients. In addition, gelatinous material occluded the dialysis catheter and apheresis tubings during the initial plasma exchange sessions, the researchers reported (Blood. 2017;129[7]:896-905).

To test the association of polyethylene oxide with thrombotic microangiopathy, the researchers heated a 40-mg Opana ER tablet cut in several pieces in a spoon with 2 mL water until boiling. They injected guinea pigs with 0.1 or 0.3 mg/kg of the extracted polyethylene oxide, either as a single dose or as five doses given at 1.5-hour intervals. A dose-dependent increase of polyethylene oxide in plasma peaked at 8 hours after the first dose was measured and paralleled with intravascular hemolysis with increased plasma concentration of free hemoglobin, schistocytes in the peripheral blood smear, and thrombocytopenia. Spiking control blood samples in vitro with polyethylene oxide did not result in hemolysis.

“Although injection abuse of prescription opioids is highly concentrated in certain regions of the United States, particularly in rural Appalachia, all physicians should be highly inquisitive of IV drug abuse when presented with cases of [thrombotic microangiopathy],” the researchers concluded.

The researchers had no relevant conflicts of interest. One of the researchers is employed by Quest Diagnostics.

mdales@frontlinemedcom.com

On Twitter @maryjodales