Drug-induced immune haemolytic anaemias

Cefazolin-induced hemolytic anemia in septic arthritis: A case report

A 50-year-old woman living with untreated HIV and injection drug use presented with right shoulder pain. The shoulder exam and computed tomography (CT) scan were concerning for septic arthritis. She was started on empiric vancomycin and cefepime and underwent right shoulder debridement and humeral head resection. Bone cultures grew methicillin sensitive Staphylococcus aureus (MSSA); empiric broad-spectrum antibiotics were changed to cefazolin. The patient subsequently developed severe anemia refractory to blood transfusions approximately 6 days later. Further evaluation disclosed hemolytic anemia attributable to cefazolin. Antibiotic therapy was switched from cefazolin to daptomycin, and the patient was started on prednisone. She had sustained improvement in hemoglobin values above 6 g/dL without requiring further transfusions prior to hospital discharge. Drug-induced immune hemolytic anemia from cefazolin is rare but has been reported primarily in the perioperative setting. Here, we present a case following initiation of treatment for septic arthritis.

Autoimmune Hemolytic Anemias: Classifications, Pathophysiology, Diagnoses and Management

Autoimmune hemolytic anemias (AIHAs) are conditions involving the production of antibodies against one's own red blood cells (RBCs). These can be primary with unknown cause or secondary (by association with diseases or infections). There are several different categories of AIHAs recognized according to their features in the direct antiglobulin test (DAT). (1) Warm-antibody AIHA (wAIHA) exhibits a pan-reactive IgG autoantibody recognizing a portion of band 3 (wherein the DAT may be positive with IgG, C3d or both). Treatment involves glucocorticoids and steroid-sparing agents and may consider IVIG or monoclonal antibodies to CD20, CD38 or C1q. (2) Cold-antibody AIHA due to IgMs range from cold agglutinin syndrome (CAS) to cold agglutin disease (CAD). These are typically specific to the Ii blood group system, with the former (CAS) being polyclonal and the latter (CAD) being a more severe and monoclonal entity. The DAT in either case is positive only with C3d. Foundationally, the patient is kept warm, though treatment for significant complement-related outcomes may, therefore, capitalize on monoclonal options against C1q or C5. (3) Mixed AIHA, also called combined cold and warm AIHA, has a DAT positive for both IgG and C3d, with treatment approaches inclusive of those appropriate for wAIHA and cold AIHA. (4) Paroxysmal cold hemoglobinuria (PCH), also termed Donath-Landsteiner test-positive AIHA, has a DAT positive only for C3d, driven upstream by a biphasic cold-reactive IgG antibody recruiting complement. Although usually self-remitting, management may consider monoclonal antibodies to C1q or C5. (5) Direct antiglobulin test-negative AIHA (DAT-neg AIHA), due to IgG antibody below detection thresholds in the DAT, or by non-detected IgM or IgA antibodies, is managed as wAIHA. (6) Drug-induced immune hemolytic anemia (DIIHA) appears as wAIHA with DAT IgG and/or C3d. Some cases may resolve after ceasing the instigating drug. (7) Passenger lymphocyte syndrome, found after transplantation, is caused by B-cells transferred from an antigen-negative donor whose antibodies react with a recipient who produces antigen-positive RBCs. This comprehensive review will discuss in detail each of these AIHAs and provide information on diagnosis, pathophysiology and treatment modalities.

Chemical- and Drug-Induced Allergic, Inflammatory, and Autoimmune Diseases Via Haptenation

Haptens are small molecules that only elicit an immune response when bound to proteins. Haptens initially bind to self-proteins and activate innate immune responses by complex mechanisms via inflammatory cytokines and damage-associated molecular patterns and the subsequent upregulation of costimulatory signals such as cluster of differentiation 86 (CD86) on dendritic cells. Subsequent interactions between CD86 and CD28 on T cells are critically important for properly activating naive T cells and inducing interleukin 2 production, leading to the establishment of adaptive immunity via effector and memory T cells. Accumulating evidence revealed the involvement of haptens in the development of various autoimmune-like diseases such as allergic, inflammatory, and autoimmune diseases including allergic contact dermatitis, atopy, asthma, food allergy, inflammatory bowel diseases, hemolytic anemia, liver injury, leukoderma, and even antitumor immunity. Therefore, the development of in vitro testing alternatives to evaluate in advance whether a substance might lead to the development of these diseases is highly desirable. This review summarizes and discusses recent advances in chemical- and drug-induced allergic, inflammatory, and autoimmune diseases via haptenation and the possible molecular underlying mechanisms, as well as in vitro testing alternatives to evaluate in advance whether a substance might cause the development of these diseases.

Serologic characteristics of oxaliplatin antibodies in 15 patients with drug-induced immune hemolytic anemia

BACKGROUND

Oxaliplatin, a third-generation platinum derivative is commonly used in combination treatment of metastatic colorectal cancer. Since 2008, it is the second most common cause of drug-induced immune hemolytic anemia (DIIHA) investigated in our laboratory.

STUDY DESIGN AND METHODS

Samples from fifteen patients including nine (60%) with intravascular hemolysis, suspected of having DIIHA were studied for the presence of anti-oxaliplatin. Direct antiglobulin tests (DATs) and tests with oxaliplatin-treated red blood cells (RBCs) or untreated and enzyme-treated RBCs in the presence of oxaliplatin were performed. A pool of normal AB sera with no unexpected antibodies was used as a control for nonimmunologic protein adsorption (NIPA).

RESULTS

Eleven (73%) of the fifteen patients had antibodies to oxaliplatin that reacted with drug-treated RBCs and untreated RBCs in the presence of drug by tube and/or gel method. Lower-titer reactivity (<20) obtained with four patients' sera and the corresponding pooled normal sera was most likely due to NIPA. Eighty seven percent (13/15) of the patients had positive DAT either with anti-IgG only (33%), IgG + C3d (40%), or C3d only (13%). Two patients had a negative DAT. No directly agglutinating antibody was observed with the pools of normal donor's sera in the presence of oxaliplatin.

CONCLUSION

Anti-oxaliplatin can cause severe intravascular hemolysis. Complement can usually be detected on the patient's RBCs and anti-oxaliplatin can be detected in the patient's serum. RBC-bound albumin detection with anti-human albumin needs to be performed to confirm NIPA which could have contributed to the patient's hemolytic anemia.

Important Pharmacogenetic Information for Drugs Prescribed During the SARS-CoV-2 Infection (COVID-19)

In December 2019, the severe acute respiratory syndrome virus-2 pandemic began, causing the coronavirus disease 2019. A vast variety of drugs is being used off-label as potential therapies. Many of the repurposed drugs have clinical pharmacogenetic guidelines available with therapeutic recommendations when prescribed as indicated on the drug label. The aim of this review is to provide a comprehensive summary of pharmacogenetic biomarkers available for these drugs, which may help to prescribe them more safely.

No Evidence for Ceftobiprole-Induced Immune Hemolytic Anemia in Three Phase 3 Clinical Trials

Purpose

Drug-induced immune hemolytic anemia (DIIHA) is a rare but serious adverse event associated with a number of drugs, including second- and third-generation cephalosporins. A positive direct antiglobulin test (DAT) is a reliable finding in DIIHA, but positive results without evidence of hemolysis can occur, particularly in hospitalized patients. There have been no reports of hemolytic anemia in four previous Phase 3 trials or from post-marketing surveillance of the advanced-generation, broad-spectrum cephalosporin, ceftobiprole. The aim of this analysis was to review the incidence of positive DAT results and any evidence of hemolytic anemia from three recent Phase 3 trials of ceftobiprole.

Patients and Methods

Patients were enrolled in three Phase 3 randomized controlled trials: 94 pediatric patients with pneumonia received ceftobiprole in the BPR-PIP-002 trial; 335 adults with acute bacterial skin and skin structure infections received ceftobiprole in the TARGET trial; and 201 adults with Staphylococcus aureus bacteremia have been randomized 1:1 to ceftobiprole or daptomycin ± aztreonam in the ongoing ERADICATE trial. In all three trials, DAT results were obtained at baseline, and follow-up tests were performed either at the test of cure (TOC) visit (BPR-PIP-002), end-of-treatment (EOT) visit (TARGET), or both EOT and post-treatment Day 70 visits (ERADICATE).

Results

In the BPR-PIP-002 trial, five patients (all ceftobiprole treated) had a documented negative DAT result at baseline followed by a positive result at the TOC visit. One patient in the ongoing, blinded ERADICATE trial had a positive DAT result at both baseline and EOT. Results from other laboratory investigations showed no evidence of hemolytic anemia in these patients. No positive DAT results were reported in the TARGET trial.

Conclusion

No evidence of hemolytic anemia associated with ceftobiprole was observed in either adults or children across several indications in this analysis of three large Phase 3 trials.