Human Blood Groups
1. Introduction
Human blood groups are classifications of blood based on the presence or
absence of specific antigens on the surface of red blood cells (RBCs). These
antigens are genetically determined and are important in:
- Blood transfusion
- Organ transplantation
- Pregnancy and fetal health
- Forensic science
- Anthropology and genetics
The most important blood group systems for NEET are:
2. Basic Terminology
Antigen (Agglutinogen)
An antigen is a substance present on RBC membrane that can stimulate
immune response. Examples:
- Antigen A
- Antigen B
- Rh antigen (D antigen)
Antibody (Agglutinin)
Antibodies are proteins present in plasma against absent antigens. Examples:
- Anti-A antibody
- Anti-B antibody
3. Discovery of Blood Groups
The ABO blood group system was discovered by Karl Landsteiner in 1900. He
received the Nobel Prize in 1930.
4. ABO Blood Group System
The ABO system is based on:
- Presence or absence of antigen A
and antigen B on RBCs
- Presence of antibodies in plasma
5. Types of ABO Blood Groups
|
Blood Group |
Antigen on RBC |
Antibody in Plasma |
|
A |
A |
Anti-B |
|
B |
B |
Anti-A |
|
AB |
A and B |
None |
|
O |
None |
Anti-A and Anti-B |
6. Principle of Blood Grouping
When incompatible blood groups are mixed:
- Antigen reacts with corresponding
antibody
- RBCs clump together
- This clumping is called agglutination
Agglutination may cause:
- Blockage of blood vessels
- Kidney failure
- Death
7. ABO Blood Group Reactions
Group A Blood
- RBCs contain antigen A
- Plasma contains anti-B antibodies
Can receive:
- A
- O
Cannot receive:
- B
- AB
Group B Blood
- RBCs contain antigen B
- Plasma contains anti-A antibodies
Can receive:
- B
- O
Cannot receive:
- A
- AB
Group AB Blood
- RBCs contain both A and B
antigens
- Plasma has no antibodies
Can receive all blood groups:
- A
- B
- AB
- O
Hence called:Universal Recipient
Group O Blood
- No A or B antigens
- Plasma contains both anti-A and
anti-B antibodies
Can donate to all groups.
Hence called: Universal Donor
(Especially O negative in practical transfusion medicine)
8. Genetics of ABO Blood Groups
The ABO blood group is controlled by gene I.
There are three alleles:
- IA
- IB
- i
9. Nature of Alleles
IA and IB
- Dominant over i
- Show codominance with each other
i allele
- Recessive
10. Genotypes and Phenotypes
|
Blood Group |
Genotype |
|
A |
IAIA or IAi |
|
B |
IBIB or IBi |
|
AB |
IAIB |
|
O |
ii |
11. Codominance
In blood group AB:
- Both IA and IB express equally
- Both antigens appear on RBC
surface
This phenomenon is called: Codominance
12. Multiple Alleles
Presence of more than two alternative forms of same gene in population is
called: Multiple Allelism. Example:
- IA
- IB
- i
13. Inheritance of ABO Blood Groups
Example
Parents:
- IAi × IBi
Possible children:
|
Genotype |
Blood Group |
|
IAIB |
AB |
|
IAi |
A |
|
IBi |
B |
|
ii |
O |
Thus, all four blood groups are possible.
14. Bombay Phenotype (Important Concept)
Discovered in Bombay (Mumbai), India.
Individuals:
- Genetically may possess IA or IB
genes
- But cannot produce H substance
required for A/B antigen formation
Therefore:
- Blood appears as O group
- Cannot receive normal O blood
Very rare condition.
15. Rh Blood Group System
Discovered in rhesus monkeys by:
- Karl Landsteiner
- Alexander Wiener
16. Rh Antigen
The most important Rh antigen is:
D antigen
17. Rh Positive and Rh Negative
|
Type |
D Antigen |
|
Rh+ |
Present |
|
Rh− |
Absent |
Most humans are Rh positive.
18. Importance of Rh Factor
Rh factor is important in:
- Blood transfusion
- Pregnancy
19. Rh Incompatibility
Occurs when:
- Rh− person receives Rh+ blood
First transfusion:
- Usually mild
- Body develops anti-Rh antibodies
Second transfusion:
- Severe agglutination and
hemolysis may occur
(Hemolytic Disease of Newborn)
A very important NEET topic.
Cause
Occurs when:
- Mother is Rh−
- Fetus is Rh+
Usually:
- Father is Rh+
21. Mechanism
First Pregnancy
- Fetal RBCs may enter maternal
blood during delivery
- Mother develops anti-Rh
antibodies
- First child usually safe
Second Pregnancy
If second fetus is Rh+:
- Maternal anti-Rh antibodies cross
placenta
- Destroy fetal RBCs
This causes:
- Hemolytic anemia
- Jaundice
- Brain damage
- Death of fetus
22. Prevention of Erythroblastosis Fetalis
Prevented by giving:
Anti-Rh antibodies (Anti-D injection)
to Rh− mother:
- Within 72 hours after first
delivery
This prevents formation of maternal antibodies.
Definition
Transfer of blood from donor to recipient.
24. Blood Compatibility Chart
|
Recipient |
Can Receive |
|
A |
A, O |
|
B |
B, O |
|
AB |
A, B, AB, O |
|
O |
O only |
25. Universal Donor and Universal Recipient
|
Type |
Importance |
|
O− |
Universal donor |
|
AB+ |
Universal recipient |
26. Cross Matching
Before transfusion:
- Donor RBCs are mixed with
recipient serum
- Tested for agglutination
Purpose:
- Prevent transfusion reactions
27. Blood Typing Procedure
Blood sample is mixed separately with:
- Anti-A serum
- Anti-B serum
- Anti-D serum
Agglutination indicates presence of corresponding antigen.
28. Other Blood Group Systems
Besides ABO and Rh:
- MN system
- Kell system
- Duffy system
- Lewis system
29. Importance of Blood Groups
Medical Importance
1. Blood Transfusion
Prevents fatal reactions.
2. Organ Transplantation
Matching reduces rejection.
3. Pregnancy
Prevents Rh incompatibility.
4. Forensic Science
Used in crime investigation and paternity testing.
5. Anthropology
Helps study human evolution and migration.
30. Blood Donation Facts
- Healthy adults can donate blood.
- Average donation: about 350–450
mL
- O negative blood is highly
valuable in emergencies.
31. Agglutination Reaction
Antigen-antibody interaction causes:
- RBC clumping
- Hemolysis
This may lead to:
- Shock
- Renal failure
- Death
32. Important Terms for NEET
|
Term |
Meaning |
|
Agglutinogen |
Antigen on RBC |
|
Agglutinin |
Antibody in plasma |
|
Agglutination |
Clumping of RBCs |
|
Hemolysis |
Destruction of RBCs |
|
Universal donor |
O− |
|
Universal recipient |
AB+ |
|
Codominance |
Equal expression of IA and IB |
|
Multiple alleles |
More than two alleles in population |
36. Quick Revision Table
|
Blood Group |
Antigen |
Antibody |
Donate To |
Receive From |
|
A |
A |
Anti-B |
A, AB |
A, O |
|
B |
B |
Anti-A |
B, AB |
B, O |
|
AB |
A & B |
None |
AB |
All |
|
O |
None |
Anti-A & Anti-B |
All |
O |
37. Mnemonic Tricks
ABO Antibodies
- A → Anti-B
- B → Anti-A
- AB → No antibodies
- O → Both antibodies
Universal Donor “O gives to all.”
Universal Recipient “AB accepts all.”
38. Summary
Human blood groups are determined by genetically inherited antigens
present on RBCs. The ABO and Rh systems are medically most important. Proper
blood matching is essential to prevent dangerous transfusion reactions and
hemolytic disease of newborns. Understanding blood groups is fundamental in
physiology, genetics, immunology, and clinical medicine.
39. NCERT-Based One-Line Revision
- Blood groups are determined by
antigens on RBCs.
- ABO system depends on A and B
antigens.
- Rh system depends on D antigen.
- IA and IB are codominant alleles.
- O group lacks antigens.
- AB group lacks antibodies.
- Rh incompatibility may cause
erythroblastosis fetalis.
- Anti-D injection prevents Rh
sensitization.