Cold haemagglutinin disease: clinical significance of serum haemolysins

Management of cold haemolytic syndrome

Most haemolytic disease is mediated by immunoglobulin G (IgG) antibodies and leads to red blood cell destruction outside of the circulatory system. However, rare syndromes, such as paroxysmal cold haemoglobinuria, show IgG antibodies causing intravascular destruction. Haemolysis may also occur because of immunoglobulin M antibodies. Historically, these antibodies have been termed 'cold agglutinins' because they cause agglutination of red blood cells at 3 degrees C. Cold agglutinin haemolytic anaemia has been associated with a number of autoimmune and lymphoproliferative disorders, and its management differs substantially from warm antibody-mediated haemolytic anaemia. This review of cold haemolytic syndromes describes new therapies and clinical strategies to determine a correct diagnosis.

Detection of serum hemolysins in autoimmune hemolytic anemia

BACKGROUND

Some patients with autoimmune hemolytic anemia (AIHA) have in their sera autohemolysins able to hemolyze RBCs in vitro by activation of complement. We describe three autohemolysins in patients with AIHA and we study clinical correlations.

STUDY DESIGN AND METHODS

Thirty-two patients with AIHA were explored by immuno-hematological investigations (DAT, elution and serum testing).

RESULTS

Three autohemolysins were detected in three patients. All of these autoantibodies were likely IgM and reacted in vitro only with enzyme-treated RBCs. Two warm autohemolysins were detected in patients with warm-type AIHA. The first one was active at neutral pH with low title. The second, having a wide thermal amplitude reacting at 22 degrees C and a title of 16, was acid. The hemolysin detected in patient 3 with cold hemagglutinin disease, was active at 4 and 22 degrees C, at acid pH. The thermal optimum was 4 degrees C and the title 64. It was also detected at 37 degrees C with the same title, but only at neutral pH.

CONCLUSION

Although these autohemolysins were incomplete, hemolyzing in vitro only enzyme-treated RBCs, they were associated for the three patients with severe hemolysis.

Agglutinines froides, circonstances de découverte chez l’adulte et signification en pratique clinique : analyse rétrospective à propos de 58 patients

PURPOSE

To describe clinical, biological characteristics and associated diseases of cold agglutinins in adults.

METHODS

Retrospective study in a single department of internal medicine from 1997 to 2002. The inclusion criteria were a positive direct Coombs test and a positive research for cold-reactive autoantibodies. We recorded for each patient: clinical presentation at onset and during follow-up, biological parameters of haemolysis, biological characteristics of the cold agglutinin and associated diseases.

RESULTS

Fifty-eight patients (34 females, 24 males), with medium age of 58.8 were included in the study. Clinical presentation was highly variable between acute life-threatening haemolysis and absence of symptoms. Results of direct antiglobulin test were C3 (74%), IgG + C3 (22.4%), IgG (3.4%). Titer, thermal amplitude, strength and specificity of Coombs test were correlated, in all cases except 6, with cold agglutinin haemolytic activity. In 77.6% of cases cold agglutinin was secondary; related to: autoimmune disorders (n = 19), lymphoproliferative disorders (n = 11) and infections (n = 10).

CONCLUSION

Clinical presentation of cold agglutinin is highly variable and not always related to the biological characteristics of the bound antibody (titer, thermal amplitude, specificity). In our single center study, diseases associated with cold agglutinin were various with the highest frequency of auto-immune disorders. Our study underlined also the high frequency of lymphoproliferative disorders and justifies a close follow-up of these patients. Finally, we reported a high frequency of hepatitis C virus infection among the infectious aetiologies.

A high-titer, high-thermal-amplitude autoanti-B associated with acrocyanosis but no obvious hemolytic anemia

BACKGROUND

ABO autoantibodies are rare. Most reported examples have been antibodies with 4 degrees C titers not greater than 256 in patients without apparent hemolytic anemia. Most high-titer, high-thermal-amplitude, complement-activating cold agglutinins are associated with hemolytic anemia.

STUDY DESIGN AND METHODS

A 52-year-old man presented with acrocyanosis and mild small-vessel brain disease, but no evidence of obvious hemolytic anemia. Regular plasmapheresis treatment was helpful in relieving the clinical symptoms associated with acrocyanosis. Serologic methods were used to study the patient's RBCs and sera.

RESULTS

The patient's RBCs were strongly reactive with anti-C3 and anti-IgM and weakly reactive with anti-IgA. The patient's serum contained a high-titer, high-thermal-amplitude, IgMkappa autoanti-B, capable of activating complement in vitro.

CONCLUSION

A patient with a powerful ABO autoantibody is described. This patient had acrocyanosis but did not appear to have an obvious hemolytic anemia. This case is a good example of the lack of correlation between in vitro serologic tests and in vivo reactions in individual patients.

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.