First Report of Reversal of Organ Dysfunction in
Transcription
First Report of Reversal of Organ Dysfunction in
From www.bloodjournal.org by guest on December 22, 2014. For personal use only. First Report of Reversal of Organ Dysfunction in Sickle Cell Anemia by the Use of Hydroxyurea: Splenic Regeneration By Susan Claster and Elliott Vichinsky Much of the morbid* associated with sickle cell anemia (SCA) is due to ongoing infarction resulting in organ dysfunction. Because the spleen is often the first organ damaged in this illness. there is a significant impairment of the immune system in thesepatients.Hydroxyurea (HU) has beenshown to increase fetal hemoglobin (HbF) anddecrease painful episodes in patients with this disease. It is unclear whether HU can prevent organ damage.We treated two SCA patients with HUfor several years and found evidence of reversal of previously documented splenic dysfunction. Patient no. 1 was treated for 30 months with an increase in HbF to 30%. HU was stopped becauseof cytopenia. She developedleft upper quadrant pain. A splenectomy was performeddue to the possibility of splenicabscesses. A pathologic review found no evidence of infection and an enlarged spleen that showed active germinal centers. Patient no. 2 was treated for 24 months with HUbefore developing splenomegaly. His HbF levels were 25% to 30%. his pit counts averaged2%, and his liver spleen scans showed uptake. Thesetwo cases show that chronic HU therapy may reverse splenic dysfunctionin certain patients and suggest that this drug may have efficacy beyond the elimination of pain in SCA. 0 7996 by The American Society of Hematology. M occasions, beginning in May 1977. Seven months later, her spleen wasno longer palpable. A liver-spleen &can performed in early 1979 showed no splenic activity. She received 5 U of blood over a 4-month period in mid 1979, and her spleen became palpable for approximately 6 months. In 1980, a pit count was 8.0%. She received transfusions again between 1984 and 1986, including a 7-U exchange transfusion in 1985; however, her spleen never again became palpable. A repeat liver-spleen scan in 1984 was unchanged. A bone scan in 1987 showed splenic activity consistent with splenic fibrosis and cal~ification.’~ She was started on HU therapy in 1987 at the age of 20. At that time, her hemoglobin level was 6.3 g/dL and her HbF was 4.1%. Thirty months later, her HbF had increased to 30%. However, several months later, her HU therapy was discontinued because of cytopenia. Her hemoglobin level decreased to 6.0 g/dL from 9.4 g/dL. Her platelet count decreased to 35,000. Her absolute neutrophil count was 2,000. She was admitted to the hospital. During that admission, she presented with left upper quadrant pain and fever. No splenomegaly was noted on exam.A computer tomography (CT) scan of her abdomen showed an enlarged spleen with focal lesions, consistent with either nodular regeneration or abscesses. Splenectomy was performed because of the concern about the latter. Her spleen weighed 294 g. Microscopic examination showed cords filled with RBCs. Reactive germinal centers were also seen, consistent with UCH OF THE MORBIDITY associated with sickle cell anemia (SCA) is the result of progressive organ damage due to sickling-induced infarction. One of the earliest organs to be damaged is the spleen.’ As the level of fetal hemoglobin (HbF) decreases to less than 15% to 20% during early childhood, the corresponding increase in hemoglobin S causes progressive dysfunction in this organ.* Youngchildren with SCA often have an enlarged but poorly functioning spleen. Eventually, the spleen completely autoinfarcts and becomes nonfunctional, resulting in significant impairment of the patient’s immune ~ y s t e m . ~ . ~ MATERIALSANDMETHODS There are two commonly used methods for evaluating splenic function. The first, radionuclide scanning, uses the uptake ofthe technetium-99 isotope, attached to a sulphur colloid particle, to show .~ the functioning of the reticuloendothelial cells of the ~ p l e e n The other method measures splenic function by quantitation of pitted red blood cells (RBCs) using phase contrast microscopy to show surface pits6 A normally functioning spleen removes these imperfections. In sickle cell disease, the level of pitted RBCs is inversely related to HbF and increases withage.’ A pit count greater than 3.5% has been determined to indicate splenic dysfunction.’ Using these techniques, previous studies have shown that transfusion therapy as well as bone marrow transplantation can reverse splenic dysfunction in certain individuals.’”’ Hydroxyurea (HU) has been administered to sickle cell patients because of its ability to increase HbF levels and thereby retard sickling.’* Previous studies have shown this drug has the ability to decrease the number of painful episodes in SCA patient^.'^ The ability of HU to sustain elevations of HbF as high as 20% to 30% in some patients suggests that the use of this drug may offer some potential reversal of organ damage without the attendant risks of transfusion. Wenow report the return of splenic function in two patients who were treated with long-term HU therapy. This is the first evidence this drug may, in fact, reverse organ dysfunction in some sickle cell patients. RESULTS Patient nu. I. Patient no. 1 is a 27-year-old woman with SCA who has had a severe clinical course. Her previous history has been characterized by multiple episodes of vasoocclusion, acute chest syndrome, and sepsis. Her spleen remained consistently palpable until the age of 10 (1977). Between the ages of 10 and 19, she was transfused on seven Blood, Vol 88, No 6 (September 15). 1996: pp 1951-1953 From the Department of Medicine, Highland General Hospital, Oakland, CA: and the Department of Hematology/Oncology Sickle Cell Program, Children’s Hospital of Northern California, Oakland, CA. Submitted December 18, 1995; accepted April 29, 19%. Supported in part by the Northern California Comprehensive Sickle Cell Cenber, a program of the Sickle Cell Disease Branch of the National Heart, Lung and Blood Institute (Grant No, HL-20985). Address reprint requests to Susan Claster, MD, The Department of Hematology, Children’s Hospital Oakland, 747 52nd St, Oakland, CA 94609. The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. section 1734 solely to indicate this fact. 0 19% by The American Society of Hematology. 0006-4971/96/8806-04$3.00/0 1951 From www.bloodjournal.org by guest on December 22, 2014. For personal use only. 1952 CLASTER AND VlCHlNSKY active immune function. There was diffuse fibrosis. No extramedullary hematopoiesis was seen and neither was there any evidence of infection. HU therapy was not restarted. Patient no. 2. Patient no. 2 is a 21-year-oldmanwith SCA who was first seen at our institution at the age of 5. At that time, a 3-cm spleen was noted on physical exam. HbF was measured at the age of 7 and found to be 13.6%. Pit counts performed at this time were 4.7%. In 198 I , at the age of 8, the HbF wasnoted to be 10.4% and a liver-spleen scan showed absent uptake of tracer. He received his first transfusion that same year and his spleen became somewhat smaller. He underwent two exchange transfusions in 1983 for priapismwithout significant change in his splenomegaly. His splenomegaly persisted until late 1988 (age 15).By January1989, his spleen was no longer palpable. He received transfusions from January through May 1989 for priapism, as well as exchange transfusions in 1990 and 1991 for acute chest syndrome.Hislast course of transfusions was from May through November 1991 foraseptic necrosis of his hips. Despite these transfusions, his spleen remained undetectable by physical exam. A bone scan performed in 199 1 showed minimal splenic activity, consistent with splenic fibrosis and calcification.I4 In January 1992, he was started on HU therapy. His pretreatment hemoglobin level was 7.0 g/dL and his HbF was 7.0%. Within 6 months, his total hemoglobin level had increased to 1 1.0 g/dL and his HbF had increased to 25% to 30%. He was maintainedon a dose of 17.0 mg/kg. His spleen was not palpableon multiple occasions. Twenty-fourmonths after starting therapy, he was noted to have palpable splenomegaly,which haspersisted for36 months.Liver-spleen scans have shown splenic uptake, and pit counts have averaged 2.0%. DISCUSSION The morbidity associated with splenic autoinfarction is of great concern to providers who care for youngpatients with SCA. Although the use of prophylactic penicillin decreases the risk of overwhelming sepsis from encapsulated organi s m ~ ,there ' ~ are now ominous reports of prophylaxis failures due to penicillin-resistant strains." Splenic dysfunction in SCA patients has previously been reported to be reversible. Pearson showed that five children with splenomegaly showed uptake on spleen scans after the level of hemoglobin S was reduced toless than 50% by transfusions.' Wethersand Grover"' reported twoyoung adults with elevated pit counts that transiently normalized aftertransfusions.Buchanan et al' found thatpatientson an intensive hypertransfusion regimen had normal or only slightlyincreased pitcountsandevidence of uptake on spleen scans. Recently, correction of splenic dysfunction in threesicklecellpatientswho underwentsuccessful bone marrow transplantation has also been shown." The exact mechanism of the HU-inducedeffecton the spleen is unclear. It is probably related to the chronic elevation of HbF and the resultantinhibitionofsickling. This mechanism is also seen in these patients with SCA who have genetically elevated levels of HbF and who have splenomegaly as adults." It is unclear what duration of HU therapy might be required to improve splenic function.Patient no. 2 clearly developed splenomegaly after 24 months on therapy, and patient no. 1 developedsplenic abnormalitieson CT scan 29months after the initiation of HU. However, pit counts and spleenscans werenotprospectivelyobtained inthesepatients. Thosepatients with ongoing functional hyposplenism who receive this drug may require a shorter period of time to show improvement. It is also possible that patients with severely fibrosed spleens will not respond at all to this drug. A prospective study involving a larger group of patients is clearly warranted to answer these questions. Transfusions have been the traditional modality for treatment of chronic complications of sickle cell disease. However, it is well known that the use of transfusions is fraught with problems, including iron overload, alloantibody formation, and infection.18 HU has now been used to treat complications such as leg ulcers and stroke when transfusions were unable to be administered.'"'" The improvement in splenic function in response to this drug suggests that other organ systems that are damaged by the effects of SCA may also respond favorably to the effects of prolonged elevations in HbF. The reversal of splenic dysfunctioninduced by HU in two young adults suggests that serious consideration should be given to administering this drug to young children.As in previous studies withtransfusions, these are thepatients with the greatest chance of reconstitution of splenic function. In fact, early HU therapy might potentially prevent functional hyposplenism in this group of patients. If this were the case, it might obviate theneed for prophylactic antibiotics. Further studies of this drug would also be aided by measurements of immune function before and after therapy. Finally, as HU use increases in SCA, more patients will receive the drug chronically. This may result in an increased incidenceof splenomegalyand functionalhyposplenism. Therefore, it is important for providers who care for these patients to evaluate the possibility of splenic infarct or sequestration in thosepatients who present with left upper quadrant pain. This isespeciallyimportant in thoseolder patients who havebeen on long-term therapy and whowould otherwise not be at risk for this complication. ACKNOWLEDGMENT The authors thank R. Vercher for her assistance in preparing this manuscript. REFERENCES I . Diggs LW: Siderofibrosis of the spleen in sickle cell anemia. JAMA 104:538, 1935 2. Pearson HA, McIntosh S, Ritchey K, Lobe1 JS, Rooks Y, Johnston D: Developmental aspects of splenic function in sickle cell disease. Blood 53:358, 1979 3. Barrett-Connor E: Bacterial infections and sickle cell anemia. Medicine 50:97, 1971 4. Pearson HA: Sickle cell anemia and severe infection due to encapsulated bacteria. J Infect Dis 136:25, 1977 (suppl) S . Pearson HA, Spenser RP, Cornelius EA: Functional asplenia in sickle cell anemia. N Engl J Med 281:923, 1969 6. Holrode CP, Oski FA, Gardner FH: The "pocked" erythrocyte. N Engl J Med 281:516, 1969 From www.bloodjournal.org by guest on December 22, 2014. For personal use only. SPLENIC REGENERATION 7. Pearson HA, Gallgher D, Chilcote R, Sullivan E, Wilimas J, Espeland M, Ritchey AK, the Cooperative Study of Sickle Cell Disease: Developmental pattern of splenic dysfunction in sickle cell disorders. Pediatrics 76:392, 1985 8. Pearson HA, Cornelius EA, Schwartz AD, Zelson JH, Wolfson SL, Spencer R P Transfusion-reversible functional asplenia in young children with sickle cell anemia. N Engl J Med 283:334, 1970 EA, VedroDA,Hamner S, 9.BuchananGR,McKieV,Jackson Holtkamp CA: Splenic phagocytic function in children with sickle cell anemia receiving long-term hypertransfusion. J Pediatr 115568, 1989 10. Wethers DL, Grover R: Reversibility of splenic function by transfusion in two young adults with sickle cell anemia. Am J Pediatr Hematol Oncol 9:209, 1987 11. Ferster A, Bryan W, Corazza F, Devalk C, Fondu P, Toppet M, Verhas M , Sanban E: Bone marrow transplantation corrects the splenic reticuloendothelial dysfunction in sickle cell anemia. Blood 81:1102, 1993 12. Charache S, Dover GJ, Moyer MA, Moore JW: Hydroxyureainduced augmentation of fetal hemoglobin production in patients with sickle cell anemia. Blood 69:109, 1987 13. Charache S, Dover GJ, Moore MD, Eckert S, Ballas SK, Koshy M, Milner PFA, Orringer EP, Phillips G Jr, Platt OS, Thomas GH: Hydroxyurea: Effect on hemoglobin F production in patients with sickle cell anemia. Blood 79:2555, 1992 14. Fischer KC, Shapiro S, Treves S: Visualization of the spleen 1953 with a bone seeking radionuclide in a child with sickle cell anemia. Radiology 122:398, 1977 15. Gaston MH, Verter JI, Woods G , Pegelow C, Kelleher J, Presbury G, Zarkowsky H, Vichinsky E, Iyer R, Lobel JS, Diamond S, Holbrook CT, Gill FM, Ritchey K, Falletta JM: Prophylaxis with oral penicillin in children with sickle cell anemia: A randomized trial. N Engl J Med 1986: 314, 1986 16. Wang W, Wong W, Williams J, Schutze G, Day S, Powars D, Chesney J: Sepsis caused by penicillin resistant pneumococcus in children with sickle cell anemia. Blood 84:410a, 1994 (abstr, SUPPI 1) 17. AI-Awamy B, Wilson WA, Pearson HA: Sickle cell disease in the Eastern province of Saudi Arabia. J Pediatr 104:7 14, 1984 18. Vichinsky EP: Transfusion therapy, in Embury SH, Hebbel RP, Mohandas N, Steinberg MH (eds): Sickle Cell Disease: Basic Principles and Clinical Practice. New York, NY, Raven, 1994, p 78 1 19. Orringer EP, Fowler VG, Teague MU, Phillips G, Parker JC: Sickle cell leg ulcers: A possible role for hydroxyurea therapy. 17th Annual Sickle Cell Center Meeting, Nashville, TN, March 14-18, 1992 (abstr) 20. Steinberg MH, Kinney TR: Hydroxyurea therapy: An alternative treatment for recurrent stroke in sickle cell disease. 19th Annual Sickle Cell Center Meeting, New York, NY, March 23-26, 1994 (abstr) From www.bloodjournal.org by guest on December 22, 2014. For personal use only. 1996 88: 1951-1953 First report of reversal of organ dysfunction in sickle cell anemia by the use of hydroxyurea: splenic regeneration S Claster and E Vichinsky Updated information and services can be found at: http://www.bloodjournal.org/content/88/6/1951.full.html Articles on similar topics can be found in the following Blood collections Information about reproducing this article in parts or in its entirety may be found online at: http://www.bloodjournal.org/site/misc/rights.xhtml#repub_requests Information about ordering reprints may be found online at: http://www.bloodjournal.org/site/misc/rights.xhtml#reprints Information about subscriptions and ASH membership may be found online at: http://www.bloodjournal.org/site/subscriptions/index.xhtml Blood (print ISSN 0006-4971, online ISSN 1528-0020), is published weekly by the American Society of Hematology, 2021 L St, NW, Suite 900, Washington DC 20036. 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