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BLOOD TYPES AND LISTS OF 'OTHER' VALUABLE BLOOD TYPING SYSTEMS USED
FOR BLOOD TYPES AND BLOOD TYPING REFERENCE AND BLOOD TEST TYPE
RESEARCH - DIFFERENCES IN BLOOD TYPES. |
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First A Word About ABO Incompatibility.
Blood Types and Blood type systems are critical to accurately evaluation and
categorizing our Blood. Transfusing a patient with the incorrect ABO group
Blood may have fatal consequences. Donor red cells may be destroyed by an
antibody in the recipient's plasma. The rapid intravascular hemolysis which
occurs in ABO incompatible transfusions can precipitate severe disseminated
coagulation (DIC), prolonged hypotension, acute uraemia and even death. It
has also been recognized that a potent anti-A or anti-B in donor Blood of
group O may destroy the A or B red cells of a non-O recipient. This,
together with the discovery of other red cell group systems, has completely
altered the significance of the term 'universal donor' which is often
applied to Blood of group O.
 Group
O Blood has neither A nor B Antigens. In the past, type O Blood was
given to anyone. Donors of Blood group O were, in years past, referred
to as 'universal donors.' Today, because of a better understanding of
the complex issues regarding immune reaction related to incompatible
donor Blood cells, type O Blood is no longer automatically seen as being
suitable in most every case. Group AB Blood has neither anti A nor anti
B antibodies, so any Blood can be transfused into it. Hence, persons
with Blood group AB have often been seen as 'universal recipients.'
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| In 1901
Karl Landsteiner discovered that when the Blood of one human being
was transfused with that of another human being, differences in their
Blood might well be the cause of shock, jaundice, and the Blood disorder
hemoglobinuria that had resulted through earlier Blood transfusions.
Landsteiner classified human Blood into A, B, and O groups and
demonstrated that transfusions between humans of group A or B did not
result in the destruction of new Blood cells and that this catastrophe
occurred only when a person was transfused with the Blood of a person
belonging to a different group. A fourth main Blood type, AB was found
in 1902 by A. Decastrello and A. Sturli.
From that time, differing Blood typing systems
have been devised. Historically the naming of Blood grouping systems has
been disorganized. The common conventions stipulating that dominant
traits be given capital letters and recessive traits be designated with
lower case letters have not been followed. Also by tradition, red cell
antigens were given alphabetical designations or were named after the
family of the antibody producer.
The International Society of Blood Transfusion (ISBT)
has instituted a numerical system of nomenclature to help standardize
red cell Blood group terminology. This convention mandates that each
system and collection has been given a number and letter designation,
and each antigen within the system is numbered sequentially in order of
discovery. As of this writing, over 20 Blood group systems and seven
antigen collections have been defined. High-prevalence or "public"
antigens and low-prevalence or "private" antigens that are not
associated with known systems or collections also are delineated in
numbered series.
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Some systems (i. e. H, Ii,
Lewis) delineate naturally occurring antibodies, but most of the other
systems give rise to iso-antibodies, which result from incompatible
transfusions and pregnancy. Following here is an ISBT Type/Class Chart. |
|
CONVENTIONAL NAME |
ISBT SYMBOL |
ISBT NUMBER |
ANTIGENS |
|
BLOOD GROUP SYSTEMS |
|
ABO |
ABO |
001 |
4 |
|
MNSs |
MNS |
002 |
37 |
|
P |
P1 |
003 |
1 |
|
Rh |
RH |
004 |
47 |
|
Lutheran |
LU |
005 |
18 |
|
Kell |
KEL |
006 |
21 |
|
Lewis |
LE |
007 |
3 |
|
Duffy |
FY |
008 |
6 |
|
Kidd |
JK |
009 |
3 |
|
Diego |
DI |
010 |
2 |
|
Cartwright |
YT |
011 |
2 |
|
Xg |
XG |
012 |
1 |
|
Scianna |
SC |
013 |
3 |
|
Dombrock |
DO |
014 |
5 |
|
Colton |
CO |
015 |
3 |
|
Landsteiner-Wiener |
LW |
016 |
3 |
|
Chido/Rogers |
CH/RG |
017 |
9 |
|
Hh |
H |
018 |
1 |
|
Kx |
XK |
019 |
1 |
|
Gerbich |
GE |
020 |
7 |
|
Cromer |
CROMER |
021 |
10 |
|
Knops |
KN |
022 |
5 |
|
Indian |
IN |
023 |
2 |
|
Ok |
OK |
024 |
- - |
|
Raph |
RAPH |
025 |
- - |
|
JMH |
JMH |
026 |
- - |
ANTIGEN
COLLECTIONS |
|
Cost |
COST |
205 |
2 |
|
Ii |
I |
207 |
2 |
|
Er |
ER |
208 |
2 |
|
P, P1, LKE |
GLOBO |
209 |
3 |
|
Lewis-like: Le-c, Le-d |
- - |
210 |
2 |
|
Wright |
WR |
211 |
2 |
Low
Prevalence |
|
Low Prevalence |
- - |
700 |
36 |
High
Prevalence |
|
High Prevalence |
- - |
911 |
11 |
|
|
The MNSs System
This system was discovered by injecting animals with human red cells. There
are two loci: M/N and S/s. The antigens are M, N, S, and s. There are
naturally occurring (IgM) antibodies to all these antigens. Anti-S and
anti-s commonly develop immune characteristics (IgG class) as a result of
pregnancy or transfusion.
The P System
This system was also discovered by injecting animals with human red cells.
P1 is the most common antigen which has variable strength of expression.
Anti-P1 may be naturally occurring. It is most often an IgM antibody.
The Lutheran
(Lu) System
This system is a single locus system, with antigens Lua and Lub. The Lu(a)
negative phenotype is very rare. Antibodies to Lutheran antigens are IgG.
The genes of the Lutheran group are linked to the genes responsible for the
secretion of ABH substances.
The Kell System
In this system there are four antigens at two loci: K (Kell) and k (cellano),
and Kpa and Kpb. The Kp(a+) phenotype and the Kp(a-b-) phenotype are both
rare. The Knull phenotype K- k- Kp(a-b-) is associated with chronic
granulomatus disease (CGD), an inherited defect in the bacterial capacity of
neutrophils. Antibodies to Kell system antigens are IgG. Named for
the family of the antibody producer Mrs. Kellacher.
The Lewis
System
This system was focuses on a single locus with two antigens, Le a and Le b.
These antigens do not form an integral part of the red cell membrane, but
are soluble antigens which may be present in body fluids and secretions.
They are adsorbed on to the surface of red cells if they are present in the
plasma in sufficient amounts. There are only three phenotypes: Le(a-b-);
Le(a+b-); and Le(a-b+). Lewis phenotypes may change during pregnancy.
Examples of Le(a+b+) are only transient. Lewis antibodies are only found in
Le(a-b-) individuals, and are almost entirely IgM. They are the only Blood
group antibodies which have never been implicated in HDN (hemolytic disease
of the newborn.)
The Duffy
System
The Duffy system is also a single locus with two antigens, Fy a and Fy b.
The only rare phenotype is Fy(a-b-), which has a higher frequency in
countries where there is a high incidence of Plasmodium falciparium
malaria. This phenotype gives a degree of immunity to the disease because
the malarial parasite requires Duffy antigens to enter the red cells. Duffy
antibodies are almost exclusively IgG. This system is named after the family of
the antibody producer, Duffy.
The Kidd (Jk)
System
Another single locus system, two antigen system (Jka and Jkb). There are
four possible phenotypes: Jk(a-b-); Jk(a+b-); Jk(a-b+); Jk(a+b+). Jk(a-b-)
is a rare phenotype. Antibodies to the Kidd antigens are almost exclusively
IgG.
Incompatible transfusion or pregnancy can lead to the formation of
antibodies to all these Blood groups, if the recipient/mother lacks the
relevant antigen. It is possible to detect all red cell antibodies using an
antibody detection panel and different detection techniques. (Some
antibodies, usually IgM class, react best at room temperature or cooler, and
some work best at 37 degrees entigrade). If an antibody is detected in a
serum the red cells from that patient are tested for the presence of the
antigen. Antigen detection techniques also vary according to the nature of
the antibody-antigen interaction. The presence of a particular antibody
specifically excludes the patient from carrying that antigen.
The Rhesus (Rh) System
The Rhesus system is the most important of the other commonly utilized Blood
grouping systems. It was discovered by Landsteiner and Weiner in 1940. Their
experiment was to produce an antibody to the red cells of the Rhesus monkey
in rabbits and guinea pigs, but they discovered that not only did the
antibody in the rodents' serum agglutinate the Rhesus monkey red cells, it
also agglutinated the red cells of 85% of the human population. If an
individual's red cells were clumped together by this antiserum, they were
said to have the Rhesus factor on their red cells (i. e. Rh positive). If an
individual's cells were not agglutinated by the antiserum, they were said to
lack the Rhesus factor (i. e. Rh negative).
The Fisher System
It is now known that the Rh system is very complex, and our present
understanding is based on the Fisher system. There are three genes making up
Rhesus antigens: C, D, and E, found on chromosome 1. There are two possible
alleles at each locus: c or C; d or D; and e or E. One haplotype consisting
of c/C, d/D, e/E is inherited from each parent, and the resulting Rhesus
type of the individual depends on their inherited genotype. The haplotypes
are given a code as follows in the table below.
|
Haplotype |
Fisher System |
| CDe |
R1 |
| cDE |
R2 |
| CDE |
Rz |
| cDe |
Ro |
| Cde |
r' |
| cdE |
r" |
| CdE |
Ry |
| cde |
r |
If an
individual's Rh genotype contains at least one of the C, D, E antigens, they
are Rhesus positive. Only individuals with the genotype cde/cde (rr) are
Rhesus negative. For Blood transfusion purposes, donors possessing C or E,
even in Rh types r'r and r''r are classed as Rh positive. Recipients of
Blood transfusions with Rh types r' and r'' should receive Rh negative (rr)
Blood. This is to prevent sensitization to Rh antigens and subsequent Rh
antibody formation. The most common Rh antibody is anti-D, but it is
possible to form antibodies to c, C, e, and E as well, and to form
combinations of antibodies. There is no anti-d
http://www.umds.ac.uk/tissue/bludgrp.html
Blood Group Details Explained from SCARF
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