Detection of bacterial contamination and DNA quantification in stored blood units in 2 veterinary hospital blood banks

Blood transfusions in veterinary medicine have become increasingly more common and are now an integral part of lifesaving and advanced treatment in small and large animals. Important risks associated with transfusion of blood products include the transmission of various infectious diseases. Several guidelines suggest what infectious agents to screen for in canine and feline transfusion medicine. However, while the risk of bacterial contamination of blood products during storage and administration has not been documented in veterinary medicine, it has emerged as a cause of morbidity and mortality in human transfusion medicine. Clinical experience shows that the majority of blood component bacterial contaminations are caused by only a few species. Unlike other types of bacteria, psychrotolerant species like Pseudomonas spp. and Serratia spp. can proliferate during the storage of blood units at 4°C from a very low titer at the time of blood collection to a clinically significant level (> 10⁵ CFU/mL) causing clinical sepsis resulting from red blood cell concentrate transfusions in human medicine. The purpose of this report was to describe the detection and quantification procedures applied in 4 cases of bacterial contamination of canine and feline blood units, which suggest the need for further investigations to optimize patients’ safety in veterinary transfusion medicine.     

In vitro lysis and acute transfusion reactions with hemolysis caused by inappropriate storage of canine red blood cell products

Background: Transfusion of red blood cell (RBC) products carries considerable risk for adverse reactions, including life‐threatening hemolytic reactions. Objective: To report the occurrence and investigation of life‐threatening acute transfusion reactions with hemolysis in dogs likely related to inappropriate blood product storage. Animals: Four dogs with acute transfusion reactions and other recipients of blood products. Methods: Medical records were reviewed from 4 dogs with suspected acute hemolytic transfusion reactions after receiving RBC products at a veterinary clinic over a 1‐month period. Medical records of other animals receiving blood products in the same time period also were reviewed. Blood compatibility and product quality were assessed, subsequent transfusions were closely monitored, and products were diligently audited. Results: During or immediately after RBC product transfusion, 4 dogs developed hemolysis, hemoglobinuria, or both. Two dogs died and 1 was euthanized because of progressive clinical signs compatible with an acute hemolytic transfusion reaction. Blood type and blood compatibility were confirmed. RBC units from 2 blood banks were found to be hemolyzed after storage in the clinic's refrigerator; no bacterial contamination was identified. After obtaining a new refrigerator dedicated to blood product storage, the problem of hemolyzed units and acute transfusion reactions with hemolysis completely resolved. Conclusions: Acute life‐threatening transfusion reactions can be caused by inappropriate storage of RBC products. In addition to infectious disease screening and ensuring blood‐type compatibility, quality assessment of blood products, appropriate collection, processing, and storage techniques as well as recipient monitoring are critical to provide safe, effective transfusions.     

Controversies related to red blood cell transfusion in critically ill patients

Objective – To review the evolution of and controversies associated with allogenic blood transfusion in critically ill patients. Data sources – Veterinary and human literature review. Human Data Synthesis – RBC transfusion practices for ICU patients have come under scrutiny in the last 2 decades. Human trials have demonstrated relative tolerance to severe, euvolemic anemia and a significant outcome advantage following implementation of more restricted transfusion therapy. Investigators question the ability of RBCs stored longer than 2 weeks to improve tissue oxygenation, and theorize that both age and proinflammatory or immunomodulating effects of transfused cells may limit efficacy and contribute to increased patient morbidity and mortality. Also controversial is the ability of pre‐ and post‐storage leukoreduction of RBCs to mitigate adverse transfusion‐related events. Veterinary Data Synthesis – While there are several studies evaluating the transfusion trigger, the RBC storage lesion and transfusion‐related immunomodulation in experimental animal models, there is little research pertaining to clinical veterinary patients. Conclusions – RBC transfusion is unequivocally indicated for treatment of anemic hypoxia. However, critical hemoglobin or Hct below which all critically ill patients require transfusion has not been established and there are inherent risks associated with allogenic blood transfusion. Clinical trials designed to evaluate the effects of RBC age and leukoreduction on veterinary patient outcome are warranted. Implementation of evidence‐based transfusion guidelines and consideration of alternatives to allogenic blood transfusion are advisable.     

Blood transfusion in the perioperative period

In the perioperative period, blood transfusions are most commonly administered to address acute blood loss resulting from trauma, neoplasia, or surgery. In this setting, transfusions may be life saving, allowing time for clotting or surgical hemostasis. In recent years, however, there is a growing awareness that the administration of blood products may not be a benign treatment. In addition to the more commonly cited complications such as transfusion reactions, disease transmission, and electrolyte disturbances, blood transfusions have also been linked to poor surgical outcomes, increased risk of infection, cancer recurrence, and acute lung injury. The recognition of these problems has lead to more conservative transfusion strategies, and questioning of what constitutes an appropriate transfusion trigger. In this section, we will discuss the pathophysiology of acute blood loss, the benefits and risks of transfusions in surgical patients, management of perioperative blood transfusions, and alternative strategies to minimize the need for blood products.     

Autologous blood transfusion following an allogenic transfusion reaction in a case of acute anaemia due to intra‐abdominal bleeding

This report describes the use of an autologous transfusion to temporarily improve the oxygen carrying capacity in a case of haemoabdomen. The horse required multiple blood transfusions but use of allogenic transfusions was hindered by a severe adverse reaction. The blood previously lost into the abdomen was drained and returned to the circulation without observed adverse effects. Autologous blood transfusion is a technique which can be used alone, or in addition to, allogenic blood transfusions in selected cases of acute blood loss in horses.     

Noncitrated blood transfusions used as adjunctive treatment in a 7‐year‐old Shetland Pony with haemoperitoneum due to a ruptured corpus haemorrhagicum

Chronic bleeding due to extensive haemorrhage from a ruptured corpus haemorrhagicum developed 2–4 weeks after parturition and was identified as the cause for a haemoperitoneum in a 7‐year‐old Shetland Pony mare, leading to anaemia. Diagnosis was made upon exploratory coeliotomy and a unilateral ovariectomy was performed. Intra‐ and post operatively, the mare received autologous blood transfusions of noncitrated blood. To our knowledge, this is the first report of an autologous blood transfusion accomplished using noncitrated blood collected from the abdominal cavity.     

Transfusion medicine in exotic pets

The decision to transfuse a patient should always be based on the packed cell volume and clinical status of the patient. This article discusses indications for transfusion and blood substitutes in exotic animal patients. The administration of blood products requires careful donor selection, knowledge of blood groups, cross-matching, and use of anticoagulants. Collection sites, volume, and administration techniques are given for different species of animals including birds, rabbits, and ferrets. Blood-transfusion therapy is not without risk. The frequency with which transfusion reactions occur in exotic pets is unknown. The most common transfusion reactions seen in small animals, along with suggested treatment, are discussed. The availability of blood products is limited in exotic pet medicine; therefore, the use of blood substitutes (Oxyglobin) has the advantage of long storage potential, no need for cross-matching, and no potential for disease transmission. General principles of blood substitutes and administration techniques will be discussed.     

Canine platelet transfusions

Objective – To review potential platelet storage options, guidelines for administration of platelets, and adverse events associated with platelet transfusions. Data Sources – Data sources included original research publications and scientific reviews. Human Data Synthesis – Transfusion of platelet concentrates (PCs) plays a key role in the management of patients with severe thrombocytopenia. Currently PCs are stored at 22°C under continuous gentle agitation for up to 5 days. Chilling of platelets is associated with rapid clearance of transfused platelets, and galactosylation of platelets has proven unsuccessful in prolonging platelet survival. Although approved by the American Association of Blood Banks, cryopreservation of human platelets in 6% DMSO largely remains a research technique. Pre‐storage leukoreduction of PCs has reduced but not eliminated acute inflammatory transfusion reactions, with platelet inflammatory mediators contributing to such reactions. Veterinary Data Synthesis – Canine plateletpheresis allows collection of a concentrate with a high platelet yield, typically 3–4.5 × 10¹¹ versus <1 × 10¹¹ for whole blood‐derived platelets, improving the ability to provide sufficient platelets to meet the recipient's transfusion needs. Cryopreservation of canine platelets in 6% DMSO offers immediate availability of platelets, with an acceptable posttransfusion in vivo platelet recovery and half‐life of 50% and 2 days, respectively. While data on administration of rehydrated lyophilized platelets in bleeding animal models are encouraging, due to a short lifespan (min) posttransfusion, their use will be limited to control of active bleeding, without a sustained increase in platelet count. Conclusions – Fresh PC remains the product of choice for control of bleeding due to severe thrombocytopenia or thrombopathia. While cryopreservation and lyophilization of canine platelets offer the benefits of immediate availability and long‐term storage, the compromise is decreased in vivo recovery and survival of platelets and some degree of impaired function, though such products could still be life saving.     

Increasing patient safety in veterinary transfusion medicine: an overview of pretransfusion testing

Objectives – To review the principles and available technology for pretransfusion testing in veterinary medicine and discuss the indications and importance of test performance before RBC transfusion.
Data Sources – Current human and veterinary medical literature: original research articles and scientific reviews.
Summary – Indications for RBC transfusion in veterinary medicine include severe anemia or tissue hypoxia resulting from blood loss, decreased erythrocyte production, and hemolyzing conditions such as immune-mediated anemia and neonatal isoerythrolysis. Proper blood sample collection, handling, and identification are imperative for high-quality pretransfusion testing. Point-of-care blood typing methods including both typing cards and rapid gel agglutination are readily available for some species. Following blood typing, crossmatching is performed on one or more donor units of appropriate blood type. As an alternative to technically demanding tube crossmatching methods, a point-of-care gel agglutination method has recently become available for use in dogs and cats. Crossmatching reduces the risk of hemolytic transfusion reactions but does not completely eliminate the risk of other types of transfusion reactions in veterinary patients, and for this reason, all transfusion reactions should be appropriately documented and investigated.
Conclusion – The administration of blood products is a resource-intensive function of veterinary medicine and optimizing patient safety in transfusion medicine is multifaceted. Adverse reactions can be life threatening. Appropriate donor screening and collection combined with pretransfusion testing decreases the occurrence of incompatible transfusion reactions.     

A newly recognized blood group in domestic shorthair cats: the Mik red cell antigen

BACKGROUND: Naturally occurring alloantibodies produced against A and B red cell antigens in cats can cause acute hemolytic transfusion reactions. Blood incompatibilities, unrelated to the AB blood group system, have also been suspected after blood transfusions through routine crossmatch testing or as a result of hemolytic transfusion reactions. HYPOTHESIS: Incompatible crossmatch results among AB compatible cats signify the presence of a naturally occurring alloantibody against a newly identified blood antigen in a group of previously never transfused blood donor cats. The associated alloantibody is clinically important based upon a hemolytic transfusion reaction after inadvertent transfusion of red cells expressing this red cell antigen in a feline renal transplant recipient that lacks this red cell antigen. METHODS: Blood donor and nonblood donor cats were evaluated for the presence of auto- and alloantibodies using direct antiglobulin and crossmatch tests, respectively, and were blood typed for AB blood group status. Both standard tube and novel gel column techniques were used. RESULTS: Plasma from 3 of 65 cats and 1 feline renal transplant recipient caused incompatible crossmatch test results with AB compatible erythrocytes indicating these cats formed an alloantibody against a red cell antigen they lack, termed Mik. The 3 donors and the renal transplant recipient were crossmatch-compatible with one another. Tube and gel column crossmatch test results were similar. CONCLUSIONS AND CLINICAL IMPORTANCE: The absence of this novel Mik red cell antigen can be associated with naturally occurring anti-Mik alloantibodies and can elicit an acute hemolytic transfusion reaction after an AB-matched blood transfusion.     

Indications and Techniques for Blood Transfusion in Birds

There is growing medical care related to emergency presentations and procedures used to treat companion and wild birds. These critical care procedures (e.g., blood transfusion) can be life-saving. To maximize the beneficial effects of blood transfusions administered to avian patients, it is necessary to have an understanding of avian hematology and erythropoiesis, recognize clinical conditions in which one performs a blood transfusion, know the proper procedures and techniques, and rapidly identify possible adverse reactions.     

Transfusion practices and costs in dogs.

A geographically stratified sample of 25 small-animal practices administering at least six transfusions to dogs over the last 12 months was surveyed to determine how veterinarians obtain blood for transfusions, the direct costs of administering transfusions, and the impact of available blood on the management of critically ill dogs. The primary source of donor blood for each practice was a borrowed dog (12 practices) or in-house dogs kept on the premises (12 practices). Only one practice obtained blood from a nearby veterinary school. There was a wide variation in practices regarding testing for diseases and screening of donors. Thirty-six percent of practices surveyed did not screen dogs for infectious diseases or evaluate hematologic variables prior to blood donation. Twenty-four percent of the respondents evaluated the donors solely for the purposes of detecting microfilaria. The remaining 40% of the practices performed one or more of the tests generally recommended as part of a screening program for potential blood donors. The blood type of donors was determined in eight of the practices, whereas blood typing of recipients was not routinely performed. Ten of 25 practices performed blood crossmatches, but only one practice performed crossmatches in all cases. The distribution of direct costs per whole blood transfusion (500-ml unit) ranged from 25 to more than $300, with three fourths of the practices having costs less than $100. The higher-cost practices were those that maintained donors on the premises specifically for blood donation purposes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Feline transfusion practice in South Africa: current status and practical solutions

Blood transfusion therapy is often under-utilised in feline practice in South Africa. However, it is a technique that can be safely and effectively introduced in practice. Cats have naturally occurring allo-antibodies against the blood type that they lack, which makes blood typing, or alternatively cross-matching, essential before transfusions. Feline blood donors must be carefully selected, be disease free and should be sedated before blood collection. The preferred anticoagulant for feline blood collection is citrate-phosphate-dextrose-adenine. Blood can either be administered intravenously or into the medullary cavity, with the transfusion rate depending on the cat's hydration status and cardiac function. Transfusion reactions can be immediate or delayed and they are classified as immunological or non-immunological. Indications, methods and techniques to do feline blood transfusions in a safe and economical way are highlighted.     

Retrospective Study: Incidence of transfusion reactions to commercial equine plasma

Objective – To report on the incidence of transfusion reactions to commercial equine plasma in a hospital‐based population of horses, to characterize these reactions and report on outcome. Design – Retrospective study. Setting – University teaching hospital. Animals – Client‐owned horses referred to the University of Wisconsin. Interventions – Intravenous administration of 2 commercial equine plasma products when clinically indicated. Measurements and Main Results – Medical records of 107 horses that received plasma transfusions between 2003 and 2008 were evaluated. Transfusion reactions were recorded in 6 of 107 transfusions. All individuals were administered plasma from 1 commercial source. Foals <30 days of age received a hypergammaglobulinemic product and all adults received a lower IgG concentration product. No reactions were recorded in adults. In foals (<30 d) reactions were recorded in 6 of 69 cases (8.7%), all of which occurred in neonates <7 days of age (6/62; [9.7%]). The most frequent reactions were fever (4/6), tachycardia (2/6), tachypnea (2/6), and colic (2/6). All affected foals survived the reaction. There were no statistically significant differences (P<0.05) in any of the variables examined between those foals that did and those that did not experience transfusion reactions. Conclusion – The incidence of transfusion reactions was 8.7% in foals and 0% in adult horses in our referral population. Five of 6 foals responded to medical therapy and eventually received the clinically indicated transfusion. No transfusion related mortality occurred.     

Platelet transfusion in thrombocytopenic horses

Platelet transfusions might be indicated in horses with thrombocytopenia. The need for a transfusion cannot be determined by platelet numbers alone, as primary or co‐existing disease processes, platelet function and age of the recipient also need to be considered. In patients with no co‐morbidities, relevant bleeding is uncommonly observed with platelet counts >10 x 10⁹/l and a therapeutic approach with initiation of treatment when signs of bleeding are observed might be justified.     

Whole blood transfusions in 91 cats: a clinical evaluation

This survey assessed the feline transfusion practices at the University of Berlin from 1998 to 2001 in regard to patient population, indications, efficacy, and transfusion reactions. Blood was obtained from seven healthy in-house donors and 127 mostly indoor client-owned pet cats. Over a 3-year period 91 cats were transfused with blood type compatible blood. The blood was fresh (within 8 h of collection) or stored no longer than 15 days. Transfusions were required because of blood loss anaemia (n=40), haemolytic anaemia (n=13), ineffective erythropoiesis (n=35), hypoproteinaemia (n=2) or coagulopathy (n=2). The anaemic cats had a pretransfusion haematocrit of 5-20% (m [median]=13), and received one to six transfusions (m=1). The survival rates of the anaemic cats at 1 and 10 days after transfusion were 84 and 64%, respectively. None of the deaths appeared to be related to transfusion reactions. The major crossmatch, undertaken before 117 transfusions, was incompatible for eight cats. All except for one had previously been transfused. Lysis of transfused cells in six cases resulted in a less than expected haematocrit rise and an increase in serum bilirubin. Transient mild transfusion reactions were only noted in two cats during the second or third transfusion. In conclusion, with proper donor selection and appropriate compatibility screening, blood transfusions are well tolerated, appear effective, and may increase chances of survival.     

Distribution of blood types in a sample of 245 New Zealand non-purebred cats

AIMS: To determine the distribution of feline blood types in a sample of non-pedigree, domestic cats in New Zealand, whether a difference exists in this distribution between domestic short haired and domestic long haired cats, and between the North and South Islands of New Zealand; and to calculate the risk of a random blood transfusion causing a severe transfusion reaction, and the risk of a random mating producing kittens susceptible to neonatal isoerythrolysis.

METHODS: The results of 245 blood typing tests in non-pedigree cats performed at the New Zealand Veterinary Pathology (NZVP) and Gribbles Veterinary Pathology laboratories between the beginning of 2009 and the end of 2014 were retrospectively collated and analysed. Cats that were identified as domestic short or long haired were included. For the cats tested at Gribbles Veterinary Pathology 62 were from the North Island, and 27 from the South Island.

RESULTS: The blood type distribution differed between samples from the two laboratories (p=0.029), but not between domestic short and long haired cats (p=0.50), or between the North and South Islands (p=0.76). Of the 89 cats tested at Gribbles Veterinary Pathology, 70 (79%) were type A, 18 (20%) type B, and 1 (1%) type AB; for NZVP 139/156 (89.1%) cats were type A, 16 (10.3%) type B, and 1 (0.6%) type AB. It was estimated that 18.3–31.9% of random blood transfusions would be at risk of a transfusion reaction, and neonatal isoerythrolysis would be a risk in 9.2–16.1% of random matings between non-pedigree cats.

CONCLUSIONS: The results from this study suggest that there is a high risk of complications for a random blood transfusion between non-purebred cats in New Zealand. Neonatal isoerythrolysis should be considered an important differential diagnosis in illness or mortality in kittens during the first days of life.     

Red blood cell transfusions in cats: 126 cases (1999)

OBJECTIVE: To determine the number of and reasons for RBC transfusions, incidence of acute transfusion reactions, prevalence of blood types, volume of blood administered, change in PCV, and clinical outcome in cats. DESIGN: Retrospective study. ANIMALS: 126 cats that received RBC transfusions. PROCEDURE: Medical records of cats that received whole blood or packed RBC transfusions were reviewed for signalment, blood type, pre- and post-transfusion PCV, volume of blood product administered, clinical diagnosis and cause of anemia, clinical signs of acute transfusion reactions, and clinical outcome. RESULTS: Mean volume of whole blood administered i.v. was 172 mL/kg (7.8 mL/lb) versus 9.3 mL/kg (4.2 mL/lb) for packed RBCs. Ninety-four percent of cats had blood type A. Mean increase in PCV among all cats was 6%. Fifty-two percent of cats had anemia attributed to blood loss, 10% had anemia attributed to hemolysis, and 38% had anemia attributed to erythropoietic failure. Acute transfusion reactions occurred in 11 cats. Sixty percent of cats survived until discharge. CONCLUSIONS AND CLINICAL RELEVANCE: RBC transfusions resulted in an increase in PCV in cats with all causes of anemia in this study. The rate of death was greater than in cats that did not receive transfusions, but seriousness of the underlying disease in the 2 groups may not be comparable. Death rate of cats that received transfusions was not attributable to a high rate of transfusion reactions. Results confirm that pretransfusion blood typing or crossmatching is required to minimize the risk of adverse reactions.