Ceftizoxime-induced hemolysis secondary to combined drug adsorption and immune-complex mechanisms

BACKGROUND: Immune hemolytic anemia has been associated with the administration of various antibiotics, including cephalosporins. Presented here is a patient who developed severe acute hemolysis while receiving ceftizoxime (Ceftizox, Fujisawa USA), a third-generation cephalosporin. This is the fourth reported case of hemolysis in association with ceftizoxime. In the previous cases, ceftizoxime was shown to induce hemolysis by the immune-complex mechanism. However, in one of those reports, the concentration of drug used to treat the target RBCs in vitro may not have been optimal. CASE REPORT: The patient's antemortem blood samples were analyzed retrospectively for drug-dependent antibodies by the drug-adsorption and immune-complex methods. Antibody class and titer were evaluated. RESULTS: The patient's sample agglutinated RBCs coated with ceftizoxime as well as uncoated RBCs in the presence of ceftizoxime. The antibodies to ceftizoxime were IgM and IgG. CONCLUSION: This is the first report on both the immune-complex and drug-adsorption mechanisms of ceftizoxime-induced hemolysis. The differential diagnosis of a falling Hct in a patient receiving antibiotics should include drug-related hemolysis; once this diagnosis is considered, management includes the appropriate serologic workup, immediate cessation of the implicated drugs, and possible transfusion support.     

First two cases of immune hemolytic anemia associated with ceftizoxime

BACKGROUND: Second- and third-generation cephalosporins have been associated with immune-mediated hemolytic reactions. This report discusses two patients who developed clinically significant extravascular hemolysis while receiving the third-generation cephalosporin ceftizoxime (Ceftizox). This is believed to be the first time hemolysis has been described in patients receiving this drug. STUDY DESIGN AND METHODS: Immunologic workup of drug-dependent antibodies was performed on blood samples using drug-coated and immune complex methodologies. Antibody classes and titers were analyzed. RESULTS: Both the patients' sera contained anti-ceftizoxime that reacted with red cells only when ceftizoxime was added to the sera ("immune complex" method). The patients recovered without complications following discontinuation of the drug. Each patient had IgM and IgG drug-dependent antibodies.The drug-induced antibodies from each patient cross-reacted with cefotaxime, which is structurally similar to ceftizoxime, but cross-reacted either weakly or not at all with ceftriaxone, which has a more complex side chain. CONCLUSION: This report describes the first cases of immune hemolytic anemia associated with ceftizoxime. In drug-induced hemolytic reactions, prompt recognition and discontinuation of the drug may be important factors in reducing the chance of serious sequelae.     

A fatal case of ceftriaxone (Rocephin)-induced hemolytic anemia associated with intravascular immune hemolysis

Fatal hemolytic anemia developed in a 52-year-old woman who was treated with a cephalosporin, ceftriaxone. The patient's red cells (RBCs) were coated with C3, but no RBC-bound IgG, IgA, or IgM was detected. Her serum contained an antibody that did not react with cephalosporin- coated RBCs but reacted strongly with RBCs in vitro when her serum was added to drug and RBCs. This is the first case of immune hemolytic anemia associated with ceftriaxone, the first case of fatal cephalosporin-induced hemolytic anemia, and the second case in which a cephalosporin antibody showed in vitro and in vivo characteristics usually thought to be associated with the so-called immune complex mechanism.     

''Immune complex'' mediated intravascular hemolysis due to IgM cephalosporin-dependent antibody

Immune hemolytic anemia (IHA) related to cephalosporins is rare and generally considered to be the result of a drug-adsorption mechanism. In previously reported cases, the hemolysis was usually extravascular and the causative antibodies were IgG, incapable of activating complement, and demonstrable by the direct or indirect antiglobulin test using red cells (RBCs) pretreated in vitro with cephalosporin. The authors report a patient in whom acute intravascular hemolysis developed while she was receiving cefotaxime (a cephalosporin as yet not reported to cause IHA). The patient's RBCs were coated only with complement fragments (C3d), even at the peak of the hemolytic episode. Her serum and eluates repeatedly yielded negative results when tested against normal or cephalosporin-coated RBCs. However, strong hemagglutination and C5b-9-mediated hemolysis were observed if the patient's serum was tested against RBCs in the presence of the drug, its ex vivo antigen and, to a lesser degree, cephalothin and ceftriaxon, but not in the presence of penicillin and other related cephalosporins. The positive reactions were not changed by preincubating the serum with different amounts of the drugs. All of these findings reflect the typical picture of drug-induced IHA by the so-called "immune complex" mechanism and not by the drug-adsorption mechanism. The authors conclude that cephalosporin can cause immune hemolysis in two ways: the drug-adsorption mechanism and, as described here, the "immune complex" mechanism.     

Sulindac-induced immune hemolytic anemia

BACKGROUND: Sulindac, a nonsteroidal, anti-inflammatory, indene-derived drug, caused life-threatening immune hemolytic anemia in an individual with back pain. CASE REPORT: A patient was admitted to the hospital with immune hemolytic anemia and kidney and liver failure after several days ingestion of sulindac. The direct antiglobulin test was positive with polyspecific and monospecific anti-IgG but not with anti-C3. The eluate did not react in routine tests but reacted strongly after the addition of sulindac. The serum contained a sulindac-dependent antibody reacting to a titer of 32. The sulindac-dependent antibody was of both IgG and IgM classes and had no apparent blood group specificity. The antibody agglutinated red cells from humans and chimpanzees but not from chickens, rabbits, or sheep, which implied that a specific component on human and chimpanzee red cells was needed for reactivity. The antibody reacted with red cells treated with trypsin, papain, pronase, dithiothreitol, and sialidase. With aggressive medical care, the patient's condition improved. CONCLUSION: These findings appear compatible with the so-called immune complex mechanism for drug-induced immune hemolytic anemia. Physicians are alerted to the severe nature of this syndrome.     

Immune hemolytic anemia caused by sensitivity to a metabolite of etodolac, a nonsteroidal anti-inflammatory drug

BACKGROUND: Immune hemolytic anemia can be caused by sensitivity to many different drugs. In some instances, the sensitizing compound can be identified by in vitro testing, but results are often negative. One reason for this is that a drug metabolite formed in vivo can be the sensitizing agent, but the responsible metabolites have rarely been identified at a chemical level. This report describes a patient who developed severe, Coombs-positive hemolytic anemia on two occasions after taking the nonsteroidal anti-inflammatory drug etodolac. Studies were performed to characterize etodolac metabolites to which this patient was sensitive. CASE REPORT: Serum was tested for antibody in the presence and absence of drug using conventional methods and urine from individuals taking etodolac as a source of drug metabolites. Urinary metabolites of etodolac were identified by high-pressure liquid chromatography analysis. Glucuronide conjugates of etodolac and the 6-OH metabolite of etodolac were synthesized in a rat liver microsomal system to obtain reference standards. RESULTS: The patient's serum gave only trace (+/-) reactions with normal RBCs in the presence of etodolac but reacted strongly (4+) in the presence of urine from an individual taking this drug. The active urinary metabolites were identified as etodolac glucuronide and 6-OH etodolac glucuronide. CONCLUSION: This patient appears to have experienced acute, severe immune hemolytic anemia on two occasions because of sensitivity to the glucuronides of etodolac and 6-OH etodolac. In patients suspected of having drug-induced immune hemolytic anemia, RBC-reactive antibodies can sometimes be detected by using urine from an individual taking the implicated medication as the source of drug metabolites in in vitro reactions. For patients who present with acute immune hemolysis, a careful history of drug exposure should be taken, and, where indicated, confirmatory testing should be performed to identify the sensitizing drug and prevent inadvertent reinduction of hemolysis at a later time.     

Kinetic studies on immune hemolysis; a method

A quantitative method for the study of the kinetics of immune hemolysis is described. In the presence of excess C' and limited amounts of antibody the kinetics of hemolysis resemble those of enzymatic processes. Assays of hemolytic antibody should therefore be based on velocity measurements rather than end point titrations.     

The first case of drug-induced immune hemolytic anemia due to hydrocortisone

BACKGROUND: Drug‐induced immune hemolytic anemia (DIIHA) is a well‐known complication of drug treatment. Sensitization can occur, due to interaction of the drug and/or its metabolites with cells of the immune system, after the first drug administration, while the hemolytic crisis generally occurs after repeated administration of a drug. This event occurred in the case described here of acute hemolysis due to the administration of corticosteroids. STUDY DESIGN AND METHODS: To define the etiopathogenesis of the hemolytic crisis, immunohematologic screening and specific tests were performed to identify antibodies against a possible drug–red cell (RBC) complex and circulating drug–anti‐drug antibody immune complexes. Six drugs administered to the patient were tested and results were confirmed by test repetition using other types of corticosteroids. RESULTS: Indirect antiglobulin test performed with the patient's serum sample on 22 RBC samples from commercial panels was strongly positive, while it was negative on RBCs from ABO‐compatible donors. The same test repeated on commercial RBCs after washing was negative. Specific tests were negative for five of the six tested drugs, while RBCs incubated with hydrocortisone strongly reacted with the patient's serum. The same tests performed using other types of corticosteroids confirmed a reaction with the same positivity score on all tested molecules. CONCLUSION: The positive reaction observed each time the patient's serum sample was incubated with RBCs in the presence of corticosteroids suggested that the triggering cause of hemolysis was an immune‐mediated mechanism and the drug responsible for DIIHA was hydrocortisone.     

Drug-induced hemolytic anemias: increasing complications to therapeutic interventions.

There are recent reports of severe drug-induced immune hemolysis caused by several different classes of drugs. Second and third generation cephalosporins, diclofenac, fludarabine, carboplatin, and beta-lactamase inhibitors are among the drugs associated with severe or fatal hemolysis. Studies on patients who exhibit hemolysis after ingesting these drugs indicate that the four classical mechanisms of drug-induced hemolytic anemia may overlap. These studies appear to support the unified theory for induction of drug-induced immune hemolytic anemia.     

Evidence suggesting the occurrence of C3-independent intravascular immune hemolysis. Reactive hemolysis in vivo

The authors present circumstantial evidence for the involvement of reactive hemolysis, i.e., C3-independent binding of the cytolytic C5b-9 complement complex to bystander red cells (RBC), in a case of intravascular immune hemolysis. Fresh serum obtained from a 6-year-old patient during the hemolytic episode, but not obtained thereafter, induced C5b-9-dependent hemolysis of human RBCs but the indirect C3 antiglobulin test remained negative. Particles (presumably RBC ghosts) isolated from the patient's plasma anticoagulated with EDTA at the peak of hemolysis were coated with C5b-9 complexes, whereas the direct antiglobulin test was strongly positive for IgA, only weakly positive for IgG, and negative for C3. Moreover, neither the autoantibodies isolated by elution (IgG plus IgA), nor free serum autoantibodies (IgA alone) activated complement in vitro. Additionally, serum samples collected later during the 12-month period of observation contained normal levels of C3, C4, C8, and C9, but markedly reduced levels of C7. These serums all produced strong reactive lysis in agarose plates, but not in test tubes. These results appear compatible with the working hypothesis that the intravascular hemolytic episode in this patient might have arisen through a local initiation of complement activation with subsequent C3-independent binding of C5b-9 to and hemolysis of bystander RBCs.     

Quantitative immunology of immune hemolytic anemia: II. The relationship of cell-bound antibody to hemolysis and the effect of treatment

The concentration of cell-bound and serum antibody was determined in a series of patients with warm antibody immune hemolytic anemia by determining the amount of C[unk]1 fixed to the cells by anti-IgG. This was compared to the rate of hemolysis as determined by hemoglobin concentration and reticulocyte count, or the endogenous production of carbon monoxide. The rate of hemolysis was, in general, proportional to the concentration of cell-bound antibody. In splenectomized patients, the rate of hemolysis was very much less than in unsplenectomized patients for a given concentration of cell-bound antibody. When prednisone was given, three effects were noted: (a) at high doses of drug, the concentration of cell-bound antibody decreased rapidly and the concentration of serum antibody increased, suggesting that the affinity of antibody for antigen had been altered; (b) in patients achieving remission, the concentration of serum antibody fell to low levels but rose again if the dose of prednisone was insufficient; (c) in one patient, prednisone appeared to inhibit sequestration of highly sensitized cells.     

Fatal immune hemolytic anemia due to cefotetan

In the first death associated with immune hemolytic anemia due to cefotetan, the patient developed hemolytic anemia and renal failure, dying 12 days after the beginning of 1 week's cefotetan therapy. The patient's serum contained strong antibodies reacting with cefotetan-treated red cells (RBCs) and with uncoated RBCs in the presence of cefotetan; a much weaker, drug-independent antibody was also detected. Three-days before the patient's death, the antibody reacting with cefotetan-coated RBCs rose to a titer of 262,144; the titer of the antibody to uncoated RBCs, in the presence of cefotetan, rose to 2048; the titer of the drug-independent antibody remained at 4.     

Aquired immune hemolytic anemias

Aquired immune hemolytic anemias are classified in autoimmune hemolytic anemia (AIHA) of warm type, cold agglutinine disease, paroxysmal cold hemoglobinuria, drug-induced immune hemolytic anemia, and paroxysmal nocturnal hemoglobinuria. The autoantibodies in AIHA of warm type react most strongly at 37 degrees C (warm autoantibodies). They are of the IgG, less commonly of the IgM and IgA classes. The cause of autoimmunization remains obscure in 50% of the patients (idiopathic AIHA). In the remaining cases, the AIHA is associated with other diseases. Corticosteroids are the mainstay of therapy, but most patients with AIHA of warm type require additional treatment with azathioprine or other drugs. Cold agglutinins are the cause of hemolysis in about 10% of patients with AIHA. Paroxysmal cold hemoglobinuria (Donath-Landsteiner) is less common and occur in children following infections. Drugs are the cause of hemolysis in about 10% of all cases with AIHA. The true incidence of alloimmune hemolytic anemias including neonatal immune hemolytic anemias is unknown. The paroxysmal nocturnal hemoglobinuria is rare. It is caused by complement activation due to aquired membrane defects.     

Delayed hemolytic transfusion reaction caused by a primary immune response

Delayed hemolytic transfusion reactions usually occur as a result of a secondary immune response with maximal hemolysis occurring seven days posttransfusion. We report a delayed hemolytic transfusion reaction in which hemoglobinuria, anemia, and reticulocytosis developed four weeks after transfusion. The incriminated antibody, anti-C, was first detected eight weeks posttransfusion using enzyme-treated red blood cells. We conclude, that in all likelihood, this hemolytic transfusion reaction was due to a primary immune response, this case illustrates the importance of sequential testing in cases of suspected transfusion reactions.     

An immediate hemolytic reaction induced by repeated administration of oxaliplatin

BACKGROUND: Platinum-based chemotherapy agents have been associated with potentially fatal acute immune-mediated hemolytic anemia. The target antigen, cause of the positive direct antiglobulin test (DAT) and mechanism of hemolysis have been the subject of controversy. CASE REPORT: We report a patient who developed a DAT-positive hemolytic episode after a red cell (RBC) transfusion was delivered during the infusion of her 17th cycle of oxaliplatin. Standard pretransfusion testing was uncomplicated; however, after infusion, the serum was no longer compatible with the transfused units and a strong (4+) panreactive IgG antibody was detected. RESULTS: The patient's serum from 10 days after the episode, only when therapeutic concentrations of oxaliplatin were added, reacted with all RBCs tested using the indirect antiglobulin test (IAT) (3+). The effect was retained with a purified IgG fraction and almost eliminated with IgG-depleted serum. Immunoprecipitation analysis revealed a band with the molecular weight of the Band 3 anion channel only in the presence of the patient's serum and oxaliplatin. CONCLUSION: Our investigations indicated that oxaliplatin interacted with both an IgG antibody and a RBC membrane epitope probably located on the Band 3 anion channel.     

Immune hemolytic anemia induced by 6-mercaptopurine

BACKGROUND: Myelosuppression is the main hematotoxic effect of 6-mercaptopurine (6-MP), which is an antimetabolite chemotherapy drug. Immune hemolytic anemia associated with this drug has not been previously reported. CASE REPORT: A 67-year-old man with chronic myelomonocytic leukemia presented with anemia 2 weeks after 6-MP therapy had been initiated. Additional tests provided laboratory evidence of hemolysis. When treatment was stopped, the patient's condition and laboratory results showed a progressive improvement. RESULTS: The direct antiglobulin test was positive for IgG. The eluate and the serum were not reactive with panel red cells but reacted with 6-MP-treated red cells, while the normal serum pool was unreactive. The direct antiglobulin test was no longer positive by 20 days after the cessation of 6-MP therapy. CONCLUSION: This drug, 6-MP, should be added to the list of drugs that have been reported to cause immune hemolytic anemia by means of the so-called hapten mechanism.     

Characterization of antibody and selection of alternative drug therapy in hydrochlorothiazide-induced immune hemolytic anemia

The authors report the clinical and laboratory findings of a patient who had severe immune hemolytic anemia due to hydrochlorothiazide (HCTZ). In this case, the HCTZ antibody reacted not only with other thiazide and thiazide-like drugs, but also with a chemically unrelated diuretic, ethacrynic acid. These results indicate that HCTZ antibody activity is not restricted solely to the thiazides and imply that therapy with any of the reactive drugs would be contraindicated for this patient. The serologic screening for drug reactivity may be useful for selecting alternative therapy for patients with drug-induced immune hemolytic anemia.     

Posttransplant immune-mediated hemolysis

BACKGROUND: Immune-mediated hemolysis is a well-recognized complication of transplantation, but few reports have drawn together the different mechanisms that could be involved. STUDY DESIGN AND METHODS: The clinical and laboratory records of three patients are used to illustrate different types and complexities of posttransplant immune-mediated RBC destruction. RESULTS: Patient 1 received bone marrow from an HLA-matched, unrelated donor. At 7 months after transplant, his Hb level fell to 50 g per L. The serum contained warm autoantibodies, and the DAT was strongly positive for IgG, IgM, and C3d; an eluate yielded IgG and IgM autoantibodies. Autoimmune hemolytic anemia was diagnosed. Patient 2, blood group A, experienced severe hemolysis 14 days after receiving a lung from a group O donor. The DAT was positive for IgG. Serum and RBC eluate contained anti-A produced by immunocompetent B cells in the transplanted lung-this was the passenger lymphocyte syndrome. Patient 3 experienced posttransplant hemolysis caused by two different immune mechanisms. Originally group A, D- with anti-C, -D, -E, she received a peripheral blood progenitor cell (PBPC) transplant from her HLA-identical group A, D+ son. Six months later, chimerism was evident; the remaining recipient marrow was still producing antibodies that destroyed D+ RBCs made by the transplant. Later, autoimmune hemolytic anemia also developed; the DAT became positive for IgG, and warm autoantibodies were eluted from D- RBCs. CONCLUSION: An understanding of the causes and circumstances under which posttransplant immune hemolysis arises is required for proper management. As more patients become long-term survivors of unrelated bone marrow and/or PBPC transplants, chimerism and complex serologic problems will become more common.     

Autoimmune hemolytic anemia associated with IgG auto anti-N

A second case of autoimmune hemolytic anemia mediated by an IgG auto Anti-N is described. The patient's red blood cells were sensitized with both IgG and complement. The serum antibody was not inactivated by 2- mercaptoethanol treatment, and reacted by indirect antiglobulin test at 37 C with monospecific anti-IgG. The IgG antibody eluted from the red blood cells and in the serum showed anti-N specificity. The patient was thought to have systemic lupus erythematosus. Following steroid therapy, the hemolytic anemia resolved with disappearance of the anti-N.     

One center's experience: the serology and drugs associated with drug-induced immune hemolytic anemia--a new paradigm

BACKGROUND: Drug-induced immune hemolytic anemia (DIIHA) is an uncommon finding characterized by a sudden decrease in hemoglobin after treatment with the putative drug. The full range of drugs causing DIIHA and the initial serologic presentation are not fully appreciated. This work identifies additional drugs associated with DIIHA and offers additional insights about diagnosis. STUDY DESIGN AND METHODS: A 20-year retrospective review of testing in one laboratory was performed. Patient sex, age, medication history, initial direct antiglobulin test (DAT) and indirect antiglobulin test, method of drug-dependent antibody (DDA) detection, and specificity were reviewed. RESULTS: Seventy-one patients with 73 DDAs to 23 different drugs were identified. The following DDA specificities were identified: cephalosporins (37), penicillin and/or penicillin derivatives (12), nonsteroidal anti-inflammatory drugs (NSAIDs) (11), quinine and/or quinidine (7), and others (6). Fifty-two percent (37) were due to cephalosporins with 27 cefotetan-dependent antibodies detected. Four NSAIDs required urinary metabolite for detection. DAT was strongly positive, at least 2+, in 75 percent (51/68) of patients with a positive DAT. Initial eluate was negative in 52 patients, weak positive (<2+) in 14 patients, and strong positive (>or=2+) in 2 patients. Serologic results showed characteristics of warm autoimmune hemolytic anemia (AIHA) in 22 or 31 percent of all cases and cold-reactive AIHA in 2 cases. CONCLUSIONS: It is important to consider DIIHA when a patient serologically presents as either warm- or cold-type AIHA to avoid erroneous diagnosis. Based on these findings, the strength of the initial DAT is much stronger than previously reported for all types of drug-induced immune hemolysis. This report is also unique in the number of NSAIDs reported. A new classification of categorizing DDA is proposed.