Pure red cell aplasia (PRCA) is a syndrome defined by a normocytic normochromic anemia with severe reticulocytopenia and marked reduction or absence of erythroid precursors from the bone marrow. Diamond-Blackfan anemia is a congenital form of PRCA. Acquired PRCA may be either a primary disorder or secondary to some other disorder or agent. Primary acquired PRCA is an autoimmune disorder that is frequently antibody-mediated. Myelodysplastic syndromes may also present with the morphologic appearance of PRCA. Secondary acquired PRCA may be associated with collagen vascular/autoimmune disorders such as systemic lupus erythematosus; lymphoproliferative disorders such as chronic lymphocytic leukemia or large granular lymphocyte leukemia; infections, particularly B19 parvovirus; thymoma and other solid tumors; or a variety of other disorders, drugs, or toxic agents. The therapeutic approach to PRCA typically involves immunosuppression, but specific pathogenic subtypes are associated with specific therapeutic approaches. Cyclosporine A, with or without concurrent corticosteroids, appears to be the single most effective immunosuppressive agent.

Learning Objectives
  • Diagnose and classify pure red cell aplasia

  • Determine treatment plans for primary and secondary immune-mediated pure red cell aplasia and for parvovirus-associated pure red cell aplasia

Pure red cell aplasia (PRCA) is a syndrome defined by a normocytic normochromic anemia with severe reticulocytopenia and marked reduction or absence of erythroid precursors from the bone marrow.1  Abnormalities from PRCA are limited to the red cell lineage; abnormalities in other cell lines usually reflect another concurrent disorder.

A classification of PRCA is outlined in Table 1. Congenital PRCA largely represents Diamond-Blackfan anemia (DBA), which is frequently associated with physical morphologic abnormalities and results from mutations in the genes for various ribosomal proteins.2  Pearson syndrome, a congenital mitochondrial disorder associated with marrow failure and exocrine pancreatic insufficiency, also exhibits erythroid precursor hypoplasia and is sometimes categorized with PRCA, but is probably better classified as a congenital sideroblastic anemia.3 

Table 1.

Classification of pure red cell aplasia

Congenital PRCA 
Diamond-Blackfan anemia 
Acquired PRCA 
Primary 
 Primary autoimmune PRCA (includes transient erythroblastopenia of childhood) 
 Primary myelodysplastic PRCA 
Secondary, associated with: 
Autoimmune/collagen vascular disorders 
 Systemic lupus erythematosus 
 Rheumatoid arthritis 
 Inflammatory bowel disease 
Other immunologic mechanisms 
 ABO-incompatible stem cell transplantation 
 Pyoderma gangrenosum 
Lymphoproliferative disorders 
 Chronic lymphocytic leukemia 
 LGL leukemia 
 Hodgkin disease 
 Non-Hodgkin lymphomas 
 Angioimmunoblastic lymphadenopathy 
 Multiple myeloma 
 Waldenstrom macroglobulinemia 
 Castleman disease 
Other hematologic malignancies 
 Chronic myelogenous leukemia 
 Chronic myelomonocytic leukemia 
 Myelofibrosis with myeloid metaplasia 
 Essential thrombocythemia 
 Acute lymphocytic leukemia 
Solid tumors 
 Thymoma 
 Gastric cancer 
 Breast cancer 
 Biliary cancer 
 Lung cancer 
 Thyroid cancer 
 Renal cell carcinoma 
 Carcinoma of unknown primary site 
Infections 
 B19 parvovirus 
 Human immunodeficiency virus 
 T-cell leukemia-lymphoma virus 
 Infectious mononucleosis 
 Viral hepatitis (hepatitis A, B, C, and E) 
 Cytomegalovirus 
Bacterial infections 
 Group C Streptococcus 
 Tuberculosis 
 Bacterial sepsis 
Drugs and toxins 
 rhEpo-induced Epo antibody-associated PRCA 
 Other drugs (Table 2
Other disorders 
 Pregnancy 
 Riboflavin deficiency 
Congenital PRCA 
Diamond-Blackfan anemia 
Acquired PRCA 
Primary 
 Primary autoimmune PRCA (includes transient erythroblastopenia of childhood) 
 Primary myelodysplastic PRCA 
Secondary, associated with: 
Autoimmune/collagen vascular disorders 
 Systemic lupus erythematosus 
 Rheumatoid arthritis 
 Inflammatory bowel disease 
Other immunologic mechanisms 
 ABO-incompatible stem cell transplantation 
 Pyoderma gangrenosum 
Lymphoproliferative disorders 
 Chronic lymphocytic leukemia 
 LGL leukemia 
 Hodgkin disease 
 Non-Hodgkin lymphomas 
 Angioimmunoblastic lymphadenopathy 
 Multiple myeloma 
 Waldenstrom macroglobulinemia 
 Castleman disease 
Other hematologic malignancies 
 Chronic myelogenous leukemia 
 Chronic myelomonocytic leukemia 
 Myelofibrosis with myeloid metaplasia 
 Essential thrombocythemia 
 Acute lymphocytic leukemia 
Solid tumors 
 Thymoma 
 Gastric cancer 
 Breast cancer 
 Biliary cancer 
 Lung cancer 
 Thyroid cancer 
 Renal cell carcinoma 
 Carcinoma of unknown primary site 
Infections 
 B19 parvovirus 
 Human immunodeficiency virus 
 T-cell leukemia-lymphoma virus 
 Infectious mononucleosis 
 Viral hepatitis (hepatitis A, B, C, and E) 
 Cytomegalovirus 
Bacterial infections 
 Group C Streptococcus 
 Tuberculosis 
 Bacterial sepsis 
Drugs and toxins 
 rhEpo-induced Epo antibody-associated PRCA 
 Other drugs (Table 2
Other disorders 
 Pregnancy 
 Riboflavin deficiency 

Modified from Lipton et al.44 

This review will primarily focus on acquired PRCA. Primary acquired PRCA is an autoimmune disorder in which an immune mechanism interrupts erythroid differentiation. This may be mediated by an autoantibody or by another immunologic process. When an autoantibody is involved, the target of the autoantibody is variable and may be at the erythroid precursor level.4  Myelodysplastic primary acquired PRCA is an uncommon presentation of myelodysplasia morphologically characterized by erythroid hypoplasia, but is pathophysiologically distinct from the other types of PRCA described in this discussion.5  Transient erythroblastopenia of childhood is an uncommon self-limited variant of primary acquired PRCA occurring between the ages of 3 months and 4 years.6  Although familial cases have been reported, it appears to be an autoimmune disorder in most cases.6 

Secondary acquired PRCA may be associated with autoimmune/collagen vascular disorders; lymphoproliferative disorders, particularly chronic lymphocytic leukemia; infections, especially B19 parvovirus; pregnancy; hematologic malignancies; nonhematologic neoplasms, of which the association with thymoma is the best known; and drugs and toxic agents. Many of the mechanisms underlying secondary acquired PRCA are immunologic, although not always antibody-mediated. This is particularly true for PRCA associated with autoimmune/collagen vascular disorders. In a number of cases of the less common associations of disorders with PRCA, particularly nonlymphoproliferative hematologic malignancies such as chronic myelogenous leukemia or nonthymoma solid tumors, the clinical course of PRCA may run independent of the course of the associated syndrome, suggesting the association is coincidental, rather than pathophysiologic.7 

Specific syndromes of secondary PRCA

B19 parvovirus-associated PRCA.

Human B19 parvovirus is responsible for the aplastic crisis seen in patients with chronic hemolytic disorders such as sickle cell anemia, and can produce chronic PRCA in immunocompromised patients.8  B19 parvovirus directly infects human erythroid progenitors through the red cell surface P antigen (globoside). Individuals whose erythroid progenitors do not express P antigen are resistant to parvovirus infection.9 

Recombinant human erythropoietin–induced antibody-mediated PRCA.

Although cases of primary autoimmune PRCA caused by de novo antibodies against endogenous erythropoietin (Epo) have been described, they are very rare. Beginning in the 1990s, reports of PRCA associated with anti-Epo antibodies in patients with renal failure treated with recombinant human Epo (rhEpo) for anemia began to appear.10  These cases were predominantly associated with subcutaneous rhEpo administration and primarily occurred outside the United States; more than 90% of cases involved a particular rhEpo product. Epidemiologic studies eventually implicated potential adjuvant effects of leachates from rubber stoppers in prefilled syringes and particular stabilizers in the specific rhEpo formulation. With resolution of these issues, new cases have become rare.11 

Thymoma-associated PRCA.

Thymoma is the disorder with the strongest historical association with secondary PRCA. At one time, it was believed that thymoma was associated with up to 50% of cases of PRCA. The finding of PRCA may precede the finding of a thymoma or may occur after its resection. Recent series suggest PRCA is found in less than 5% of patients with thymoma.12  Among patients presenting with PRCA, the frequency of thymoma appears to be somewhere in the 7% to 10% range (the retrospective nature of many reports makes it difficult to definitively separate cases of PRCA that developed after thymectomy).13,14 

Lymphoproliferative disorder–associated.

The lymphoproliferative disorders most frequently associated with PRCA are chronic lymphocytic leukemia and large granular lymphocyte (LGL) leukemia,15,16  although it has been reported with Hodgkin and non-Hodgkin lymphoma, as well as Waldenstrom macroglobulinemia, as outlined in Table 1. A number of small studies have suggested an increased frequency of otherwise unapparent clonal T-cell disorders in primary acquired PRCA.17  PRCA is typically immune mediated in these cases, although usually not by antibody-dependent mechanisms.18 

Drugs and chemicals.

At least 50 drugs and chemicals have been associated with PRCA. The list includes a number of “usual suspects” for hematologic toxicity, such as diphenylhydantoin, azathioprine, and isoniazid.19 Table 2 lists several drugs implicated in PRCA, according to a PubMed review. Many of the reported associations derive from single case reports. Studies of underlying mechanisms are infrequent. PRCA associated with some drugs such as diphenylhydantoin and rifampicin has been linked to IgG-mediated inhibition of erythropoiesis.20,21  A number of agents implicated in PRCA do not appear in Table 2, such as benzene, halothane, methazolamide, phenobarbital, sulfathiazole, thiamphenicol, and tolbutamide, as these particular reports are not indexed in PubMed (frequently because they antedate the indexing range).

Table 2.

Selected drugs associated with PRCA based on PubMed review

AgentMultiple reportsMechanism investigated
Alemtuzumab   
Allopurinol ✓  
Ampicillin   
Azathioprine ✓ ✓ 
Carbamazepine ✓  
Cephalothin   
Cladribine   
Chlorpropamide ✓  
Chloroquine   
Clopidogrel   
Dapsone/pyrimethamine ✓  
Diphenylhydantoin ✓ ✓ 
Recombinant Epo ✓ ✓ 
Estrogens   
Fenoprofen ✓  
Fludarabine ✓  
Interferon-α ✓  
Isoniazid ✓ ✓ 
Lamivudine ✓  
Leuprolide ✓  
Linezolid ✓  
Micafungin   
Mycophenolate mofetil ✓  
d-Penicillamine ✓  
Phenylbutazone   
Procainamide ✓  
Ribavirin ✓  
Rifampicin  ✓ 
Sulfasalazine ✓  
Sulindac   
Tacrolimus ✓  
Trimethoprim/sulfamethoxazole ✓  
Valproic acid ✓ ✓ 
Zidovudine ✓  
AgentMultiple reportsMechanism investigated
Alemtuzumab   
Allopurinol ✓  
Ampicillin   
Azathioprine ✓ ✓ 
Carbamazepine ✓  
Cephalothin   
Cladribine   
Chlorpropamide ✓  
Chloroquine   
Clopidogrel   
Dapsone/pyrimethamine ✓  
Diphenylhydantoin ✓ ✓ 
Recombinant Epo ✓ ✓ 
Estrogens   
Fenoprofen ✓  
Fludarabine ✓  
Interferon-α ✓  
Isoniazid ✓ ✓ 
Lamivudine ✓  
Leuprolide ✓  
Linezolid ✓  
Micafungin   
Mycophenolate mofetil ✓  
d-Penicillamine ✓  
Phenylbutazone   
Procainamide ✓  
Ribavirin ✓  
Rifampicin  ✓ 
Sulfasalazine ✓  
Sulindac   
Tacrolimus ✓  
Trimethoprim/sulfamethoxazole ✓  
Valproic acid ✓ ✓ 
Zidovudine ✓  

PubMed search performed May 15, 2016. Search terms used were “red cell aplasia” AND the name of the specific drug.

Pregnancy.

Pregnancy has been associated with PRCA and usually (although not always) resolves after delivery.22  Occurrence of PRCA with a pregnancy does not necessarily predict recurrence with a subsequent pregnancy. The possibility of B19 parvovirus infection should be considered.

ABO-incompatible stem cell transplantation.

PRCA after ABO-incompatible bone marrow or stem cell transplant is observed most commonly with the combination of a blood group A donor and a blood group O recipient. It was reported in 7.5% of cases of ABO-incompatible transplant in 1 recent series. Although there is a high frequency of spontaneous resolution after a period of transfusion support (sometimes lasting months), 30% to 40% of cases will result in chronic PRCA requiring additional measures.23 

Clinical presentation

There is no specific clinical presentation of primary acquired PRCA; the signs and symptoms are only those associated with anemia. Because PRCA is a pure underproduction anemia, the gradual decline in hemoglobin concentration allows some degree of adaptation, and symptoms may be less than would be expected for the degree of anemia. Patients with secondary PRCA may of course manifest the symptomatology of the associated syndrome.

Laboratory findings/diagnostic evaluation

Peripheral blood counts.

Red cells in PRCA are normochromic and normocytic. The absolute reticulocyte count is always less than 10 000/µL (reticulocyte percentage, <1%), and in many cases is much lower. The diagnosis of PRCA should be questioned with higher reticulocyte values or if the reticulocyte percentage is only less than 1% when corrected for the degree of anemia. In general, the white blood count, white blood cell differential, and platelet count are normal. In the setting of concurrent inflammation, there may be some modest reduction in the total white blood count or a mild abnormality (either slightly high or slightly low) in the platelet count. There may also be a mild relative lymphocytosis.

Bone marrow morphology.

The diagnosis of PRCA requires a bone marrow examination. In primary acquired (autoimmune) PRCA, marrow cellularity and myeloid and megakaryocyte maturation are normal. The diagnosis of PRCA is based on the absence or near absence of erythroblasts from an otherwise normal marrow (<1% erythroblasts on the marrow differential count). In some cases, a few proerythroblasts and/or basophilic erythroblasts are seen, not exceeding 5% of the differential count. Large proerythroblasts with vacuolated cytoplasm and pseudopodia (“giant pronormoblasts”) are suggestive of B19 parvovirus infection, but are not diagnostic24  (Figure 1). There may be some slight increase in lymphocytes, lymphoid aggregates, and/or plasma cells, reflecting a degree of immune/inflammatory activation. Iron stains will typically be normal. Because of the paucity of erythroid precursors, ring sideroblasts are difficult to see. If present, ring sideroblasts favor a myelodysplastic syndrome, as would marked hypercellularity.

Figure 1.

Bone marrow aspirate specimen from human immunodeficiency virus–infected patient with PRCA as a result of parvovirus. Giant pronormoblasts near the center of the field (100×).

Figure 1.

Bone marrow aspirate specimen from human immunodeficiency virus–infected patient with PRCA as a result of parvovirus. Giant pronormoblasts near the center of the field (100×).

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Cellular immunology/cytogenetics.

As with all diagnostic examination of the bone marrow for cytopenias, material should be collected for cellular immunology, cytogenetics, and clonal analysis of T-cell receptors. Abnormal cytogenetics in the setting of a characteristic marrow for PRCA indicates the myelodysplastic variant of PRCA. If increased lymphocytes or plasma cells are present, they should be polyclonal in acquired immune PRCA. If clonal lymphocytes are present, it suggests PRCA secondary to an associated lymphoproliferative disorder. T-cell-receptor gene rearrangement studies should be performed routinely.17 

Parvovirus studies.

In all patients with marrows diagnostic of PRCA, B19 parvovirus testing should be performed. The test of choice is polymerase chain reaction testing on peripheral blood.

Radiologic studies.

In adults with PRCA and no evidence of parvovirus infection or of a disorder associated with secondary PRCA, a computed tomography scan of the chest should be performed to rule out a thymoma, which would have potential therapy implications.

General comments

The treatment of PRCA associated with thymoma, B19 parvovirus infection, ABO-incompatible stem cell transplantation, antibody-mediated inhibition induced by rhEpo, or pregnancy will be discussed later. DBA is typically treated with glucocorticoids, usually prednisone. Hematopoietic stem cell transplantation has also been used in patients unresponsive to glucocorticoids at sustainable doses.25  Myelodysplastic primary PRCA should be treated as appropriate for a myelodysplastic syndrome.5  If the patient is using a medication associated with PRCA, and no other PRCA-associated syndrome is present, a trial of drug discontinuation should be considered. If an infectious disorder associated with PRCA is present, specific treatment of that disorder should be initiated. Similarly, if chronic lymphocytic leukemia, Hodgkin or non-Hodgkin lymphoma, or other lymphoproliferative disorders are complicating PRCA, treatment of those disorders should be initiated.

Otherwise, for primary acquired autoimmune PRCA, PRCA with LGL leukemia, PRCA associated with solid tumors, or secondary PRCA refractory to other therapy, the treatment of choice is immunosuppression. In principle, PRCA secondary to autoimmune/collagen vascular disorders may respond to therapy specific to the management of those disorders. In practice, the treatment of these disorders is usually immunosuppression, and in cases where alternative disease-modulating therapy is available, the patient is usually referred to the hematologist because it was ineffective. The goal of treatment is to attain a normal hemoglobin concentration without any requirement for transfusion; a partial response is attainment of transfusion independence with a low but clinically acceptable hemoglobin concentration.

Immunosuppression/immunomodulation

Table 3 lists pooled data from 4 series evaluating immunosuppressive therapy in PRCA.1,13,26,27  Overall, repeated trials of immunosuppression using a succession of agents can produce a response in approximately 2/3 of patients with PRCA. The traditional immunosuppression approach began with oral corticosteroids, usually prednisone, in doses similar to those used for immune thrombocytopenic purpura (1 mg/kg). Overall, this approach appears to have a 40% response rate. Prednisone is tapered after a response is obtained, or decreased and used in association with another agent if remission is not obtained.

Table 3.

Response of patients with PRCA to immunosuppression

Agent usedPatients treated (responders/total)% responding
Corticosteroids 50/128 39% 
Cytotoxic agents 46/113 41% 
Cyclosporine A 37/48 77% 
Antithymocyte globulin 10/19 53% 
Multiple agents 91/133 68% 
Agent usedPatients treated (responders/total)% responding
Corticosteroids 50/128 39% 
Cytotoxic agents 46/113 41% 
Cyclosporine A 37/48 77% 
Antithymocyte globulin 10/19 53% 
Multiple agents 91/133 68% 

Total patients treated, n = 195 (many patients did not respond to treatment or suffered relapses, so 1 patient may be included in more than one treatment modality); primary PRCA, n = 137; secondary PRCA (n = 58). Modified from Lipton et al.44  Results pooled from 4 series.1,13,26,27 

The most effective immunosuppressive agent is cyclosporine A. Its overall response rate of more than 75% is particularly impressive, given that a number of the early series reporting its use consisted largely of patients who had failed a number of therapeutic modalities previously.4,13  Cyclosporine can be considered the agent of choice for immunosuppression in PRCA,1  or it can be considered the second-line agent after corticosteroids. A reasonable starting dose is 6 mg/kg daily. It is sometimes used in association with prednisone 30 mg/day.4  Cyclosporine trough levels should be monitored with target levels of 150 to 250 ng/mL.1  Renal and hepatic function should also be monitored. After normalization of the hemoglobin concentration, cyclosporine can be tapered slowly. Maintenance therapy may be required.14 

Cytotoxic agents such as azathioprine or cyclophosphamide (usually in combination with oral corticosteroids) have been used in patients unresponsive to corticosteroids alone, or in patients who do not respond to cyclosporine. The response rate in this context is approximately 40%. Tacrolimus has also been reported to be effective in PRCA and may provide an alternative to cyclosporine,28  but has also been reported as a cause of PRCA (Table 2). Rituximab, a humanized anti-CD20 monoclonal antibody, appears to have some efficacy against primary autoimmune PRCA,29  but is mainly used in PRCA secondary to lymphoproliferative disorders.30  Antithymocyte globulin, in the doses used for treatment of aplastic anemia, has a 50% response rate in primary autoimmune PRCA (Table 3). Modalities used in refractory primary PRCA with relatively low response rates include intravenous immunoglobulin,31  plasma exchange,32  splenectomy,33  and bone marrow transplantation.34 

The Japanese PRCA Consortium has provided long-term follow-up data on patients with PRCA after immunosuppressive therapy.14  The median survival for patients with primary autoimmune PRCA had not been reached at 250 months. For patients with LGL or thymoma-associated PRCA, median survivals were similar at 147.8 and 142.1 months, respectively. The principal causes of death were infection and organ failure. Factors predictive of death were refractoriness to therapy and relapse from response.14 

Treatment of B19 parvovirus-associated PRCA

As noted earlier, every patient with diagnosis of PRCA should be tested for B19 parvovirus. A diagnosis of B19 parvovirus associated PRCA is an indication for intravenous immunoglobulin as specific and highly effective therapy. A course of intravenous immunoglobulin for this purpose uses the usual therapeutic dose employed for disorders such as immune thrombocytopenic purpura: 2 g/kg usually divided over 5 days (400 mg/kg/d).8  In a recent review of an institutional experience and the published literature,35  the vast majority were significantly immunocompromised. PRCA corrected after a first course of intravenous immunoglobulin in 93% of patients, but approximately one-third relapsed, at mean time to relapse of 4.3 months.35 

Thymoma-associated PRCA

If a thymoma is present in a patient with PRCA, it generally should be resected. Although earlier studies reported more optimistic results, no more than a third of patients will experience remission, and responses may be less than normalization of hemoglobin concentration.36  Relapses are frequent, and PRCA may develop after resection of a thymoma in patients who did not have PRCA previously.37  Adjuvant immunosuppressive therapy is typically required.36,37  The question of the value of thymectomy in PRCA likely requires reexamination. This will be a challenge requiring a multiinstitutional effort, as no single institution is likely to have more than a few cases.

PRCA after ABO-incompatible stem cell transplantation

As discussed earlier, ABO-incompatible stem cell transplantation can result in the generation of isohemagglutinins directed against donor red cell antigens also expressed on red cell precursors, leading to PRCA.23,38  There is a high frequency of spontaneous resolution, but prolonged transfusion support may be required. If antidonor isohemagglutinins persist longer than 2 months after transplant, the likelihood of spontaneous remission is reported to be low.38  Approaches taken to mitigate this problem include adjustment in the immunosuppressive regimen, donor leukocyte infusion, plasma exchange, and rituximab treatment.38 

rhEpo-induced antibody-mediated PRCA

As discussed earlier, recognition of the factors that contributed to the unexpected development of anti-Epo antibodies in patients with renal failure and consequent presentation with PRCA has largely eliminated this mechanism as a cause of new cases of PRCA.39  However, patients with this significant problem may still be under the care of hematologists. Immunosuppression should be initiated, with cyclosporine A (with or without corticosteroids) as the probable first choice. Kidney transplantation should also be considered, if that is a possibility.40  Successful rechallenge with rhEpo in patients who no longer have detectable antibodies has been described in various case reports, but should be regarded as high-risk and is generally not recommended. Rechallenge with intravenous rhEpo has been suggested as a potentially less immunogenic strategy, but even that approach has resulted in a recurrence of PRCA.41 

Pregnancy-associated PRCA

Because of the rarity of this syndrome, there is very little experience to guide management recommendations. Most patients will have resolution of PRCA at the end of pregnancy and can be supported with transfusion as needed; prednisone has also been used for immunosuppression.22,42  The majority of reported pregnancies result in a live delivery at term if anemia is controlled.43  Cyclosporine and other immunosuppressive agents may have significant effects on fetal outcome and maternal morbidity and probably should be avoided. Testing for B19 parvovirus and treatment of patients with positive results is reasonable.

PRCA should be suspected in patients with an isolated anemia associated with marked reticulocytopenia. The diagnosis requires bone marrow examination demonstrating the absence or near absence of erythroblasts from an otherwise normal marrow. Evaluation of acquired PRCA should focus on identifying patients with myelodysplastic syndrome presenting with erythroid hypoplasia or PRCA associated with drugs, with B19 parvovirus infection, with thymoma, or with lymphoproliferative disorders, for whom syndrome-specific management is required. For other patients with primary or secondary acquired PRCA, the treatment of choice is immunosuppression. Cyclosporine A, with or without concurrent corticosteroids, appears to be the single most effective immunosuppressive agent.

Many years ago, the author was introduced to PRCA by Sanford Krantz and Emmanuel Dessypris and learned the techniques of hematopoietic cell culture from Ken-ichi Sawada, who, with his colleagues from the Japanese PRCA Consortium, continues the rich tradition of translational research in PRCA. The mentorship and intellectual generosity of these friends and colleagues are gratefully acknowledged.

Robert T. Means Jr, Office of the Dean, James H. Quillen College of Medicine, East Tennessee State University, C200 Stanton Gerber Hall, PO Box 70694, Johnson City, TN 37614; e-mail: meansr@etsu.edu.

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Author notes

This article was selected by the Blood and Hematology 2016 American Society of Hematology Education Program editors for concurrent submission to Blood and Hematology 2016. It is reprinted with permission from Blood 2016, Volume 128.

© 2016 by The American Society of Hematology. All rights reserved.

Competing Interests

Conflict-of-interest disclosure: The author declares no competing financial interests.

Off-label drug use: None disclosed.