Hyperhemolysis in a patient withβ-thalassemia majorR. Lakmali Morawakage, B. J. C. Perera1, P. D. N. Dias1, S. K. Wijewardana1Abstract:A case of hyperhemolysis in a 2-year-old boy with β thalassemia major was noted. After several transfusions, hedeveloped hyperhemolysis with a positive (C3d only) direct antiglobulin test (DAT) and no clinically significant RBC allo orauto-antibodies. (There was a weak cold antibody, showing a narrow thermal range). Because there was no significantimprovement with steroid and immunoglobulin infusions, cyclophosphamide therapy was tried with notable success.Key words:β- thalassemia, direct antiglobulin test, hyperhemolysis, transfusionIntroductionThe term hyperhemolysis is applied when thepost-transfusion hemoglobin (Hb) level is less thanthe pre-transfusion level, suggesting destructionof both the patients own red blood cells (RBCs)and the transfused RBCs. The mechanism ofhyperhemolysis is not well understood although ithas been well described in patients with sickle celldisease. Transfusion of antigen-negative cross-matchcompatible RBCs does not prevent hyperhemolysis.Serologic studies of post-transfusion and follow-upsamples may show a negative or positive (complementonly) direct antiglobulin test and usually no RBCantibodies, leaving the hemolysis unexplained (i.e.,there is no evidence of red cell antigen + antibodymediatedimmune destruction). In a mild form, theoption is to stop transfusion to avoid exacerbating thehemolysis. In severe forms, further transfusions havebeen given successfully only with concurrent IVIgand IV steroid therapy. Recurrent hyperhemolysisis fortunately rare and is unpredictable.Awareness of the potential for recurrenthyperhemolysis is important because, where possible,alternative therapy should be sought and transfusionshould be avoided. For patients with past historyof recurrent hyperhemolysis, if transfusions arerequired, use of concurrent IVIg and steroids shouldbe considered. Note, however, that because infusionof IVIg has been associated with renal toxicity,thrombosis and estimated 0.6% risk of stroke, its useshould be selective.Case ReportA two-year-old Sri Lankan Tamil boy, diagnosedwith β thalassemia major 6 months ago, wastransferred to the tertiary care hospital for childrenfor the management of severe anemia. His hemoglobinon arrival was 3.1 g/dl, even though he had received600 ml of RBC transfusions on two consecutive days,Þ ve days ago. Six months earlier, when he was Þ rstdiagnosed with β thalassemia, he was started onmonthly RBC transfusions that lasted three months,and then the transfusion interval was graduallyreduced to every few days due to very low pretransfusionhemoglobin levels.At the time of transfer, the patient was severelypale and deeply icteric with a large spleen (8 cm) andliver (3 cm) but there were no signs of heart failure.The diagnosis of β thalassemia major was conÞ rmedby high performance liquid chromatography(HPLC). Both parents were diagnosed as having thethalassemia trait. Transfusions with leukoreducedred cells matched for Rh and Kell antigens weregiven at 4-6 day intervals. The patient developedfever on and off but his clinical condition generallyremained the same with high total serum bilirubinof 137 μmol/l with indirect serum bilirubin of 115μmol/l. Coagulation screen, renal function testsand serum proteins were normal, and there was noevidence of G6PD deÞ ciency or malarial infection. Ablood culture was negative. A bone marrow biopsyshowed a poorly managed major hemoglobinopathywith increased iron stores and no evidence of anystorage diseases.Serological investigations confirmed his bloodgroup as O R1R1 with a phenotype of K-, k+, Fya+,Fyb+, Jka+, Jkb-, Lea-, Leb+, MMss. There was a weakcold autoantibody reactive only in undiluted serumin NISS below 20oC. The DAT was positive (2+) withC3d only. Unexpected antibodies were not detectedin any of the serum samples. An eluate could not bedone due to the low Hb level.Despite transfusion with cross-match compatible,leukoreduced and phenotype-selected blood in doses[Downloaded free from http://www.ajts.org on Thursday, February 12, 2009]Asian J Transf Sci - Vol 3, Issue 1, January 2009 27of 20 ml/kg, the patient continued to hemolyze. Oral prednisoloneand azothioprin were given with no apparent improvement.Azothioprin was stopped due to elevated liver enzymes and thediscovery of free ß uid in the abdomen. Addition of intravenousimmunoglobulin at 0.4 g/kg/day for 7 days showed no therapeuticbeneÞ t. High doses of cyclophosphamide therapy at 50 mg/kg weregiven in two doses, three days apart. During the cyclophosphamidetherapy, the size of the spleen reduced to 4 cm, and the DAT becamenegative for C3d. A weakly reactive DAT with anti-IgG was noted,possibly attributable to immunoglobulin therapy. While receivinginitial cyclophosphamide therapy, the patient developed a lowerrespiratory tract infection with positive radiological Þ ndings that wassuccessfully treated with intravenous antibiotics. After the seconddose of cyclophosphamide, the patient became more lethargic withHb level of 2.7 g/dl. Transfusion of Rh and Kell phenotype-matchedRBCs was given in a dose of 20 ml/kg. His post-transfusion Hb was 6g/dl with no evidence of hyperhemolysis and an obviously improvedclinical condition. Hemoglobin was around 6 g/dl for about threeweeks and was followed by regular monthly transfusions.DiscussionA case of hyperhemolysis causing severe anemia in a patient withβ thalasemia major, who continued to hemolyze despite use ofleukoreduced and phenotype-matched transfusions was reported.He had no demonstrable clinically signiÞ cant RBC antibodies at anytime but showed a positive DAT with C3d only which disappearedafter immunosuppressive therapy with cyclophosphamide. The exactpathogenesis of hyperhemolysis is complex and poorly understood.It involves destruction of both transfused and autologous RBCs.Hyperhemolysis was Þ rst recognized in patients with sickle celldisease.[1-3] It is rarely reported in thalassemic patients.[4] Sometheories that have been proposed based on observations principallyof sickle cell patients who are chronically transfused includesuppression of erythropoiesis, hyperactive macrophages causingbystander hemolysis, defective regulation of complement, andantibodies below the limit of detection of current serologic method,IgA antibodies or possibly HLA antigen-antibody reactions. In sicklecell disease patients, hyperhemolysis is commonly associated withreticulocytopenia, which may reß ect suppression of erythropoiesis.[2] However, responses to steroids suggest something more thanerythropoiesis suppression may be involved in its pathogenesis.In the absence of RBC antibody-mediated hemolysis, hyperactivemacrophages could be responsible for destruction of the patientsown red cells as well as the transfused cross-match compatiblecells.[3]The RBCs of patients with sickle cell anemia have defectiveregulation of the complement membrane attack complex.[5] Thisdefect may make sickle cells more susceptible to bystanderhemolysis in which immune complexes cause lysis of bystander,antigen negative red cells.[1,2,6,7] In this case there is no detectablealloantibody. Red cell destruction can occur by antibody-dependentcell mediated cytotoxicity (ADCC) with levels of antibody thatare below the serological detection threshold. Cell mediated lysisindependent of antibody may occur for red cell antigens in theabsence of detectable antibody.[8-10] Some red cells express HLAantigens and HLA antibodies and can cause red cell hemolysis.[11,12]Hemolysis due to HLA antigen and antibody reaction by hyperactivemacrophages and bystander hemolysis of HLA antigen negativetransfused cells could be another possible mechanism of red celllysis with no detectable red cell alloantibody. [13] Incomplete IgAantibodies can produce hemolysis with negative Þ ndings usingcommon serological techniques.[14] 51Chromium-labelled red bloodcell survival studies, if available, should be considered wheneveran unexplained hemolytic transfusion reaction occurs, or when anexpected red blood cell alloantibody cannot be demonstrated by invitro laboratory studies.[15]This patients dramatic response to cyclophosphamide suggeststhat cyclophosphamide can be used in patients with hyperhemolysiswhere transfusion is unavoidable due to other associated medicalconditions.References1. Garratt y G. Severe reactions associated with transfusion of patientswith sickle cell disease. Transfusion 1997;37:351-61.2. Petz LD, Calhoun L, Shulman LA, Johnson C, Herron RM. Thesickle cell haemolytic transfusion reaction syndrome. Transfusion1997;37:382-92.3. Win N, Yeghen T, Needs M, Chen FE, Okpala I. Use of intravenousimmunoglobulin and intravenous methylprednisolone inhyperhaemolysis syndrome in sickle cell disease. Haematology2004;9:433-6.4. Grainger JD, Marker Y, McManus A, Wynn R. Refractory hyperhaemolysisin a patient with B-thalasaemia major. Transfus Med2001;11:55-7.5. Test ST, Woolworth VS. Defective regulation of complement by thesickle erythrocyte: Evidence for a defect in control on membraneatt ack complex formation. Blood 1994;83:842-52.6. Sirchia, G, Morelati F, Rubulla P. The sickle cell haemolytic transfusionreaction syndrome. Transfusion 1997;37:1098-9.7. King KE, Shirly RS, Lankiewicz MW, Young-Ramsaran J, Ness PM.Delayed hemolytic transfusion reactions in sickle cell disease: Simultaneousdestruction of recipients red cells. Transfusion 1997;37:376-81.8. van der HART, Engelfriet CP, Prins HK, van Loghem J. A haemolytictransfusion reaction without demonstrable antibodies in vitro. VoxSang 1963;8:363-70.9. Baldwin ML, Barrasso C, Ness PM, Garratt y G. A clinically signiÞ -cant erythrocyte antibody detectable only by 51Cr survival studies.Transfusion 1983;37:357-61.10. Gilsanz F, De La Serna J, Molto L, Alvarez-Mon M. Haemolyticanaemia in chronic large granular lymphocytic leukemia of naturalkiller cells: Cytotoxicity of natural killer cells against autologous redcells is associated with haemolysis. Transfusion 1996;36:463-6.11. Benson K, Agosti SJ, Latoni-Benedett i GE, Lepare GF. Acute anddelayed haemolytic transfusion reactions secondary to HLA alloimmunization.Transfusion 2003;43:753-7.12. Panzer S, Matyr WR, Graninger W, Puchler K, Hocker P, LechnerK. Haemolytic transfusion reactions due to HLA antibodies: Aprospective study combining red cell serology with investigationsof chromium-51-labelled red cell kinetics. Lancet 1987;28:474-8.13. Win N, Doughty H, Telfer P, Wild BJ, Pearson TC. Hyperhaemolytictransfusion reaction. Transfusion 2001;41:323-8.14. Greenberg MS, Jandl JH. The selective destruction of transfusedcompatible red cells in patients with splenomegaly. J Lab Clin Med1975;49:233-45.15. Davey RJ, Gustafson M, Holland PV. Accelerated immune red celldestruction in the absence of serologically detectable alloantibodies.Transfusion 1980;20:348-53.