Blood loss is a common cause of anemia in kidney transplant patients. In the immediate post-transplant period, intraoperative blood loss and blood loss related to frequent phlebotomies are common causes of anemia. In the first few weeks after transplantation, patients frequently get multiple vials of blood drawn to monitor kidney function, screen for viral infections and also to adjust the doses of immunosuppression medications. In one study, average blood loss related to operative and phlebotomy losses in the first 12 weeks after transplantation was approximately 755–860 mL [17]. This can quickly result in profound anemia, especially if there is preexisting iron deficiency at the time of kidney transplantation or if allograft function is poor. Fortunately, in most patients, brisk production of erythropoietin from the new allograft negates the drop in hemoglobin, despite blood draws.

Later in the post-transplant period, causes of anemia due to blood loss change and include gastrointestinal bleeding and menstrual blood losses. Common causes of gastrointestinal bleeding include gastritis, peptic ulcer disease, diverticulosis, and arterio-venous malformations [18, 19]. While transplant medications, including steroids and mycophenolate, can cause gastritis and significant gastric erosions, infectious etiologies including cytomegalovirus can also play a role. Other rare causes of bleeding include post-transplant lymphoma in GI tract and Kaposi sarcoma.

In women, abnormal uterine bleeding is a common cause of anemia. When on dialysis, hypothalamic–pituitary–ovarian axis dysfunction can lead to menstrual irregularities, anovulation, and infertility [20, 21]. After kidney transplantation, ovarian axis dysfunction may improve resulting in regular menstruation cycles. Similarly, fertility can also be restored with normal kidney function. But in some transplant patients, despite normal allograft function, luteal insufficiency may persist and premature ovarian failure can occur. It is not uncommon to see menorrhagia worsen after kidney transplantation. Unless specifically asked, women often do not report excessive menstrual blood losses to the transplant physician. The slow decline in hemoglobin and mean corpuscular volume (MCV) levels should prompt the physician to inquire about menstrual losses. If confirmed, patients should be referred early to a gynecologist. It is also important to rule out other structural lesions, including endometrial carcinoma and uterine fibroids. In women with significant menstrual losses, parenteral iron may be frequently necessary to keep up with ongoing losses. When indicated, hysteroscopic endometrial ablation is a safe and effective procedure in transplant patients [22]. However, in some women, hysterectomy may be needed. Kidney transplant patients who undergo hysterectomy have higher incidence of perioperative complications, but surgery does not affect graft outcome [23].

The majority of medications used in kidney transplant recipients to prevent acute rejections and opportunistic infections can cause PTA. While anemia related to myelosuppression is common, there are unique aspects that deserve special mention.

Pure red cell aplasia (PRCA) can occur in transplant recipients from a wide variety of causes. PRCA is a syndrome characterized by anemia, usually severe, very low reticulocyte count and complete absence of erythroid precursors on bone marrow examination. In PRCA, WBC and platelet counts are normal. PRCA has been rarely reported with the use of mycophenolate and the exact mechanism is unknown. PRCA is sometimes reversible with dose reduction or withdrawal of the drug. Other medications that have been associated with PRCA include azathioprine, sulfonamides, INH, phenytoin, zidovudine, valproic acid, and clopidogrel.

In addition to medications, PRCA can also be associated with parvovirus B-19 infection. By attaching to the blood group P antigen receptor, parvovirus directly destroys proerythroblasts, resulting in PRCA. In this condition, bone marrow examination is characterized by the presence of giant proerythroblasts. The diagnosis is confirmed with the presence of parvovirus B-19 DNA in the serum, and also with anti-B19 IgM antibodies in serum. In some patients, anemia is refractory and may need frequent blood transfusions and multiple doses of intravenous immune globulin (IVIg) infusions. In addition to Parvo-viral infection, several other viral etiologies including viral hepatitis, cytomegalovirus, Epstein–Barr virus, and HIV infection have been reported to cause PRCA.

An acute drop in hemoglobin concentration in the immediate post-transplant period is most likely related to a combination of intra-operative blood loss and dilutional component from over-zealous fluid replacement in the post-operative period, especially when there is delayed graft function. If the drop is significant and disproportionate, imaging study is warranted to rule out bleeding complication and hematoma formation.

Anemia noted in the outpatient setting is often related to persistent EPO or nutritional deficiencies, transplant drugs or infections. Anemia should warrant complete work up including checking red blood cell indices (mean corpuscular volume, mean corpuscular hemoglobin, mean corpuscular hemoglobin concentration), reticulocyte count, iron studies (serum iron, total iron binding capacity, serum ferritin), folate, and vitamin B12 concentrations. In patients with iron deficiency, stool occult blood should be checked and if positive, will need complete gastrointestinal work up including endoscopy. In women, menstrual blood losses should be ruled out as the cause of anemia. Since nutritional deficiencies are easily correctable, it is prudent to rule them out first. If there is no nutritional deficiency, peripheral blood smear is often helpful, along with search for evidence of hemolysis, including serum LDH, indirect bilirubin, and haptoglobin levels. Peripheral smear is often helpful to diagnose microangiopathic hemolysis (schistocytes).