Erythrocyte antigens and the immune system

Question 1

What is the significance of understanding the interaction between antigens and antibodies in transfusion medicine?

Answer 1

Understanding the interaction between antigens and antibodies is crucial in transfusion medicine because it helps prevent immune reactions against transfused cells, ensuring recipient safety.

Question 2

How are transfused exogenous cells treated by the recipient’s immune system?

Answer 2

Transfused exogenous cells are treated as ‘foreign’ by the recipient’s immune system, initiating an immune response similar to what occurs when targeting invading microorganisms.

Question 3

What are antigens, and what can they stimulate?

Answer 3

Antigens are molecules present on the surface of infectious organisms, drugs, pollens, and cells. They can stimulate an immune response by binding to lymphocyte receptors. Alloantigens are those originating from the same species.

Question 4

What determines the strength of the immune response to antigens, and why are highly antigenic antigens clinically significant?

Answer 4

he strength of the immune response to antigens depends on antigenicity, influenced by properties like complexity, biological activity, and size. Highly antigenic antigens are more clinically significant in red cell transfusions.

Question 5

What happens when transfusions bypass innate responses and activate adaptive immune responses?

Answer 5

Transfusions bypass innate responses and activate adaptive immune responses, involving humoral (B lymphocytes producing antibodies) and cellular (T lymphocytes that destroy target cells) pathways.

Question 6

What is complement activation, and how is it implicated in transfusion reactions?

Answer 6

Complement activation refers to a group of plasma proteins involved in immune responses. It is implicated in type II hypersensitivity reactions in transfusion recipients. There are four pathways for complement activation: classical, lectin, alternative, and terminal.

Question 7

What are the four effects of complement activation, and how do they impact transfusion reactions?

Answer 7

The four effects of complement activation are cell lysis (target cell destruction), inflammation, opsonization (coating the target cell for phagocytosis), and interactions with other pathways. In transfusion, these effects can lead to recipient issues such as hemolysis and inflammation.

Question 8

What is cellular immunity, and how does it function in the immune response?;

Answer 8

Cellular immunity is the immune response initiated by T lymphocytes to non-self antigens. T-lymphocytes differentiate into T helper cells (B-lymphocyte support) and T cytotoxic cells (directly destroy target cells).

Question 9

What is the role of memory T-lymphocytes in the immune response?

Answer 9

Memory T-lymphocytes retain the memory of an antigen for future encounters, while other T-lymphocytes are involved in the immediate immune response.

Question 10

How does T-lymphocyte differentiation allow the immune response to be more concentrated on specific aspects?

Answer 10

The differentiation of T-lymphocytes into T helper cells and T cytotoxic cells allows the immune response to be concentrated on either antibody production or the destruction of target cells, depending on the presented antigen.

Question 11

What happens once a compatible T-lymphocyte is found in the immune response?

Answer 11

When a compatible T-lymphocyte is found, it requires three activating signals to initiate the immune response. Once fully activated, the T-lymphocyte transforms into a lymphoblast and secretes cytokines, which induce immune actions.

Question 12

What are antibodies, and how are they produced?

Answer 12

Antibodies, or immunoglobulins, are a class of gamma globulins. They are produced and secreted by antigen-specific B lymphocytes, particularly B lymphoblasts, which are the activated form of the cell.

Question 13

What are the stages of B lymphocyte activation upon recognizing a non-self antigen?

Answer 13

Activated B lymphocytes, or lymphoblasts, undergo three stages of activation upon recognizing a non-self antigen. Most activated B cells differentiate into plasma cells that synthesize and secrete specific antibodies, with some becoming memory B cells.

Question 14

What is the primary immune response, and when does it become clinically significant?

Answer 14

The primary immune response is the body’s reaction to a new non-self antigen, with a natural lag phase. It is initially mediated by IgM but shifts to IgG after a few days, which is more clinically significant.

Question 15

What is the secondary immune response, and how does it differ in dogs and cats?

Answer 15

The secondary response occurs in sensitized dogs or all cats transfused with incompatible blood. It is primarily mediated by memory B lymphocytes producing IgG antibodies and is considerably more potent and rapid.

Question 16

Why is the secondary response more rapid and potent in cats, especially on their first transfusion?

Answer 16

The secondary response is more rapid and potent in cats on their first transfusion because they naturally have circulating antibodies to non-self red cell antigens. This response is mediated by memory B lymphocytes, even in the absence of prior exposure.

Question 17

What does the term “Blood type” refer to?

Answer 17

Blood type refers to species-specific antigens present on the surface of erythrocytes.

Question 18

Define “Blood group system” in the context of transfusion medicine.

Answer 18

A blood group system is one or more red cell antigens controlled by either a single gene or a cluster of two or more closely linked, homologous genes.

Question 19

What does “Autosomal” refer to?

Answer 19

Autosomal refers to the characteristic being located on non-sex chromosomes.

Question 20

Explain the term “Dominant” in the context of genetics.

Answer 20

Dominant refers to the relationship between two genes controlling the same characteristic, where the dominant gene is always expressed, masking the manifestation of recessive genes.

Question 21

Define “Locus” in genetics.

Answer 21

Locus refers to the location of a gene controlling a particular characteristic, indicating a specific position on a chromosome.

Question 22

What is an “Allele”?

Answer 22

An allele is a different version of a gene found at the same locus, resulting in variations in the expression of a characteristic.

Question 23

What is a “Monoclonal” sample?

Answer 23

A monoclonal sample consists of identical antibodies recognizing an antigen at the same antigen-antibody binding site (epitopes), ensuring high specificity.

Question 24

Define “Polyclonal.”

Answer 24

Polyclonal refers to a sample containing a mixture of antibodies capable of identifying the same antigen but at different antigen-antibody binding sites (epitopes).

Question 25

Who discovered the ABO blood group system, and when?

Answer 25

Karl Landsteiner, an Austrian doctor, discovered the ABO blood group system in 1900.

Question 26

How many blood groups are recognized in the DEA system for dogs?

Answer 26

Currently, seven blood groups in the DEA system are recognized: DEA 1, DEA 3, DEA 4, DEA 5, DEA 6, DEA 7, and DEA 8.

Question 27

Are erythrocyte antigens genetically determined, and do they change over an individual’s lifetime?

Answer 27

Yes, erythrocyte antigens are genetically determined characteristics, similar to eye color, and they do not change over an individual’s lifetime.

Question 28

What is the significance of the positive and negative designations in blood types?

Answer 28

If the gene controlling the expression of a particular antigen is present at the locus, that antigen will be expressed (positive), and if not present, the antigen will not be expressed (negative).

Question 29

What are “natural antibodies,” and when are they present in dogs and cats?

Answer 29

Natural antibodies are present in dogs or cats without any antigen exposure. They are generated soon after birth or can be maternal antibodies passed from mother to offspring.

Question 30

How does the prevalence of an antigen impact incompatibility reactions during transfusion?

Answer 30

An antigen with high prevalence causes fewer incompatibility reactions, as most individuals express the antigen, reducing the likelihood of antibody generation following a transfusion.

Question 31

What are the two types of haemolytic transfusion reactions, and what influences them?

Answer 31

Acute haemolytic transfusion reactions occur during or within 24 hours of a transfusion, while delayed reactions can be primary or secondary immune responses, influenced by the antigenicity of the antigen.

Question 32

What is unique about DEA 7 compared to other erythrocyte antigens?

Answer 32

DEA 7 is an unusual antigen as it is not part of the cell membrane but is soluble, manufactured by lymphocytes, secreted into plasma, and then absorbed onto the surface of RBCs.

Question 33

How was the Dal antigen discovered, and in which breeds is it found?

Answer 33

Dal antigen was discovered in 2007 in a Dalmatian. Breeds like Dobermans, Dalmatians, Shih Tzus, Lhasa Apsos, Bichon Frises, and mixed breeds have been found to be Dal negative.

Question 34

What technique was used to identify Kai antigens, and how prevalent are they in dogs?

Answer 34

Kai antigens were identified using mouse hybridoma techniques. Kai 1 is prevalent in 94% of dogs, and dogs cannot express both Kai 1 and Kai 2.

Question 35

What is unique about Kai antigens in terms of expression and natural antibodies?

Answer 35

Naturally occurring alloantibodies to Kai antigens do not appear to occur, but alloantibody production occurs following a Kai incompatible transfusion, and the clinical significance of repeated Kai exposure is not yet known.

Question 36

What are the three recognized feline blood types?

Answer 36

The three recognized feline blood types are Type A, Type B, and Type AB (also referred to as C).

Question 37

How is the feline blood type determined at the molecular level?

Answer 37

Feline blood types are determined by the presence or absence of the enzyme Cytidine monophospho-N-acetylneuraminic acid hydroxylase (CMHA), which influences the conversion of neuraminic acid residues on the erythrocyte surface.

Question 38

What is the role of the CMHA gene in determining feline blood types A, B, and AB?

Answer 38

Type A: The CMHA gene is active, allowing NeuAc to NeuGc conversion. NeuGc is the dominant neuraminic acid in the erythrocyte membrane.
Type B: The CMHA gene is mutated and not active, resulting in only NeuAc present in the erythrocyte membrane.
Type AB: The CMHA gene is active, and both NeuAc and NeuGc are equally present at low levels.

Question 39

Differentiate between “Homozygous” and “Heterozygous” in genetics.

Answer 39

Homozygous: An individual with two identical alleles controlling a single characteristic.
Heterozygous: An individual with two different alleles controlling a single characteristic.

Question 40

How are natural alloantibodies produced in cats?

Answer 40

Natural erythrocyte alloantibodies are produced after exposure to antigens similar to erythrocyte antigens from sources such as plants, bacteria, and protozoa that kittens are unavoidably exposed to after birth.

Question 41

What blood type is most common in non-pedigree cats, and which breeds are associated with it?

Answer 41

Type A is the most common blood type in non-pedigree cats. Breeds such as Siamese, Tonkinese, and Burmese have a 100% reported occurrence of Type A.

Question 42

What are the characteristics of anti-B alloantibodies in Type A cats?

Answer 42

Anti-B alloantibodies in Type A cats have weak agglutinising and haemolysing actions with low titres (≤ 32 and often ≤ 8).

Question 43

Describe the reactions following transfusion of Type B or Type AB red cells to a Type A recipient.

Answer 43

Reactions are generally mediated by IgG and IgM, resulting in a delayed transfusion reaction and a marked reduction in erythrocyte survival post-transfusion. Immune sensitization to the Type B antigen occurs, and a second exposure may result in a more profound immune response.

Question 44

What is the prevalence of Type B blood in cats?

Answer 44

Type B blood is much less common, occurring in 4-7% of cats, including breeds like British Shorthair, Devon Rex, and Turkish Angora.

Question 45

What are the characteristics of anti-A alloantibodies in Type B cats?

Answer 45

Type B cats have high titres (64-1024) of anti-A alloantibodies, which are potent haemolysins and haemagglutins, causing severe and potentially fatal acute haemolytic reactions.

Question 46

What is the prevalence of Type AB blood in cats?

Answer 46

Type AB blood is universally rare across all cat populations, occurring in 1-3% of cats.

Question 47

What is the Mik antigen, and how was it discovered?

Answer 47

The Mik antigen was discovered in a cat named Mike, a Type A blood recipient that developed marked haemoglobinaemia and hyperbilirubinaemia following a Type A packed red blood cell transfusion.

Question 48

What is Feline Neonatal Isoerythrolysis (FNI)?

Answer 48

Feline Neonatal Isoerythrolysis (FNI) is a condition where circulating alloantibodies in the plasma of breeding cats cause serious consequences and death for some kittens, primarily when a Type B queen mates with a Type A Tom.

Question 49

What clinical signs are associated with FNI in kittens?

Answer 49

Clinical signs of FNI include dark brown urine, haemoglobinuria, jaundice, anaemia, weakness, and necrosis of the tail tip in surviving kittens.

Question 50

How is FNI diagnosed?

Answer 50

A cross-match can be performed to identify incompatibility between the red cells of the kitten and the plasma of the queen, or the kitten and queen can be blood typed. Kittens with FNI will be Coomb’s test positive, supporting the antigen-antibody-mediated component of the condition.

Question 51

How can FNI-affected kittens be managed?

Answer 51

Affected kittens should be removed from the queen until they are over 24 hours old, fed by hand during this time, and provided with supportive care such as warmth, nutrition, and oxygen. A transfusion of washed red cells may be necessary.

Question 52

How can FNI be prevented?

Answer 52

FNI can be prevented by avoiding incompatible matings. Both parents can be blood typed, and if the queen is Type B and the Tom is Type B, there is no risk of Type A kittens. If the Tom is Type A, removing the kittens from the queen for 24 hours can prevent colostrum ingestion.

Question 53

What is the significance of the Mik antigen in blood typing?

Answer 53

The prevalence of the Mik antigen is not well-documented, but it can lead to red cell incompatibility in cats. Natural anti-Mik alloantibodies may occur, and their titres vary among anti-Mik cats.

Question 54

What can be considered for colostrum-deprived kittens?

Answer 54

Early vaccination may be considered for colostrum-deprived kittens to provide them with vital early protection.

Question 55

What is the significance of erythrocyte antigens in transfusions?

Answer 55

Erythrocyte antigens have a significant impact on recipient safety, causing clinical consequences and reducing the lifespan of transfused red cells. They can minimize the benefits of a transfusion and cause serious complications, especially when incompatible antibodies are present.

Question 56

How can the compatibility between the recipient and blood product/donor be assessed prior to a transfusion?

Answer 56

Compatibility can be assessed through blood typing and type matching. Blood typing determines the blood type of an individual, and the International Society of Animal Genetics (ISAG) standardizes blood-typing antisera to ensure accuracy.

Question 57

What is serology, and what does it involve in the context of transfusions?

Answer 57

Serology is the study of in vitro antigen-antibody binding. In transfusions, serological tests are performed to establish recipient-donor compatibility before the transfusion.

Question 58

Describe the card agglutination test for blood typing in cats.

Answer 58

In the card agglutination test, whole blood is collected into an EDTA sample tube and tested using cards with wells containing lyophilized antibodies or antibody-mimicking agents specific to the antigen being tested. The absence or presence of macroscopic agglutination determines the blood type.

Question 59

What is the significance of the prozone effect in card agglutination tests?

Answer 59

The prozone effect in card agglutination tests results in brief agglutination that disappears. It occurs when antigen or antibody levels are extremely high, reducing the capacity for immune complexes to form. Adding an additional drop of buffer may help in diluting the antibody concentration

Question 60

How does stearic hindrance affect feline Type A well in card agglutination tests?

Answer 60

Stearic hindrance can occur in the feline Type A well with anaemic patients, where fewer erythrocytes mean fewer antibody binding sites. To address this, the manufacturer recommends not adding buffer to the feline ‘Patient Test’ wells with low pack cell volume (PCV).

Question 61

What is the accuracy of card agglutination tests compared to other typing methods?

Answer 61

Card agglutination tests are reported to have the lowest accuracy, around 91.4%, compared to other canine and feline typing methods.

Question 62

What is an immunochromatographic strip, and how is it used in blood typing?

Answer 62

Immunochromatographic strips are porous paper strips impregnated with monoclonal antibodies. They are used for in-house testing, and if the antigen is present in the patient sample, it binds to the antibody, producing visible lines. Control lines ensure correct test performance.

Question 63

What are the recommended practices for using immunochromatographic strips?

Answer 63

It is recommended to perform typing twice for all first-time donors, using two separate blood samples, two test kits, and two different operators. This is comparable to human good practice standards.

Question 64

What is back typing, and how is it used in transfusion compatibility testing?

Answer 64

Back typing, or antibody screening, involves mixing red cells of a known blood type with serum or plasma from an individual to look for agglutination, indicating an antigen-antibody incompatibility. It is essentially the same as a major cross match.

Question 65

When did in-house automated typing become available, and what does it determine in canines and felines?

Answer 65

In-house automated typing became available in 2011 with the QuickVet®/RapidVet® analyzer. In canines, it determines DEA 1, and in felines, it determines blood type based on the absence or presence of agglutination using species-specific cartridges.

Question 66

What does the analyzer assess using species-specific cartridges, and how does it determine blood type?

Answer 66

The analyzer assesses the intensity of transmitted light from each channel in the cartridge. When no agglutination is present, red cells distribute homogeneously; agglutination results in sections without red cells. The difference in light absorption helps identify the patient’s blood type.

Question 67

What are the limitations of the automated typing method?

Answer 67

The automated method is not accurate in severely agglutinating, hemolyzed, or very low (less than 4%) or very high (over 60%) samples.

Question 68

Describe the gel method for blood typing.

Answer 68

The gel method involves diluting a patient sample in a blood preparation tube, adding drops to control and reaction tubes, waiting 5 minutes, and then centrifuging. Results are based on the interaction of Type A or Type B antigens with antibodies in the gel.

Question 69

What results indicate Type A, Type B, and Type AB in the gel method?

Answer 69

In the gel method, Type A results in agglutinated cells above the gel, Type B accumulates at the bottom, and Type AB shows dispersed agglutinated cells throughout the gel block.

Question 70

What is the tube method, and when is it typically used?

Answer 70

The tube method, considered the gold standard, is used by external laboratories for extended typing. Erythrocytes are incubated with antibodies for a specific antigen, then centrifuged and evaluated for haemolysis and agglutination.

Question 71

How is antibody titre defined, and what does it represent?

Answer 71

Antibody titre is defined as the reciprocal of the highest serum dilution giving an unequivocally positive reaction in a serological test. It represents a concentration range determined by sequentially doubling the sample dilution until a negative reaction occurs.

Question 72

What is the alloantibody titre naturally present in cats against AB antigens?

Answer 72

The anti-A alloantibody titre of Type B cats is between 64-1024, and the anti-B alloantibody titre of Type A cats is low, often ≤ 32 and ≤ 8.

Question 73

How is blood type used for product selection in dogs and cats?

Answer 73

Blood typing is used to match red cell donor type to recipient type, always for cats, and preferably but not essential for the first dog transfusion. Plasma donor type is matched to recipient type in cats. In emergencies, DEA negative red cells are given to dogs.

Question 74

What should be considered when giving DEA positive red cells to a DEA 1 negative recipient?

Answer 74

If given DEA positive red cells to a DEA 1 negative recipient, accurate typing will be prevented until the positive cells are cleared from circulation, which may take up to 90 days or longer.

Question 75

What is the prozone effect in agglutination reactions?

Answer 75

The prozone effect occurs when there are too few antigenic binding sites for the level of antibody. An excess of antibody can result in a false negative result when it cannot react with the antigen.

Question 76

What is the significance of macroscopic agglutination, and how does it differ from microscopic agglutination?

Answer 76

Macroscopic agglutination is visible to the naked eye and is generally stronger. Microscopic agglutination, on the other hand, is only visible under a microscope and is weaker.

Question 77

Describe the major crossmatch in the context of blood transfusions.

Answer 77

The major crossmatch involves mixing the recipient’s plasma with the donor’s erythrocytes. This is done prior to red blood cell transfusions to reduce the risk of serious acute and delayed immunological adverse reactions, allowing transfused cells to have the optimum lifespan in the recipient.

Question 78

Explain the Rouleaux phenomenon and its significance.

Answer 78

Rouleaux is the stacking of red blood cells, often seen in healthy cats. It can resemble macroscopic agglutination, but in saline tests, it helps prevent misinterpretation as it dissociates Rouleaux.

Question 79

What is the purpose of the minor crossmatch in transfusions, and when is it necessary?

Answer 79

The minor crossmatch involves mixing donor plasma with recipient red cells. In felines, where naturally occurring alloantibodies are present, all feline plasma or whole blood transfusions should be assessed using a minor crossmatch.

Question 80

When is it necessary to perform a major crossmatch in feline transfusions?

Answer 80

For the first feline whole blood transfusion and subsequent feline whole blood transfusions, both major and minor crossmatches are recommended. For the first feline PRBC transfusion, a major crossmatch is needed, and for subsequent feline PRBC transfusions, a major crossmatch is also recommended.

Question 81

What is the Feline Emergency Matching Test (EmMa), and when is it used?

Answer 81

EmMa is a combination major and minor crossmatch kit used prior to whole blood transfusion in felines. It incorporates immunochromatographic technology and requires two cell and plasma mixtures to be created, showing both major and minor crossmatch results.