Thursday, February 22, 2024

Vaccines

History of vaccination

For centuries, human beings have looked for ways to be protected from deadly diseases and thus vaccination has a long history. Vaccines have saved more human lives than any other medical invention in history.

·        From as early as 200 BCE and during the 15th century, people in different parts of the world have attempted to prevent illness by intentionally exposing healthy people to smallpox and this practice was termed as variolation. In 1721, Lady Mary Wortley Montagu brought smallpox inoculation to Europe by inoculating her two daughters against smallpox as she had observed this practice in Turkey. 

·        In 1774, Benjamin Jesty hypothesised that infection with cowpox could protect a person from smallpox.  In May 1796, English physician Edward Jenner e inoculated 8-year-old boy, James Phipps, with matter collected from a cowpox sore on the hand of a milkmaid. Phipps suffered a local reaction and felt unwell for several days.  Two months later, in July 1796, Jenner inoculated Phipps with matter from a human smallpox sore and Phipps becomes the first human to be vaccinated against smallpox. The term ‘vaccine’ was later coined by Louis Pasteur (From the Latin word for cow, vacca).

·        In 1872, Louis Pasteur created the first laboratory-produced vaccine - vaccine for fowl cholera in chickens. In 1885, Louis Pasteur successfully prevented rabies through post-exposure vaccination. Pasteur gave a course of 13 injections containing rabies virus to a rabid dog bitten boy, Joseph Meister. Meister survived and later becomes the caretaker of Pasteur’s tomb in Paris.

·        In 1894, Dr Anna Wessels Williams isolated a strain of the diphtheria bacteria that was used for the development of diphtheria antitoxin.   In 1937 Max Theiler, Hugh Smith and Eugen Haagen developed the 17D vaccine against yellow fever and Theiler was awarded Nobel Prize.

·        In 1939, bacteriologists Pearl Kendrick and Grace Eldering demonstrated the efficacy of the pertussis (whooping cough) vaccine. By 1945 -1946 the first influenza vaccine was approved through the research led by Thomas Francis Jr and Jonas Salk.

·        From 1952–1955, the first effective polio vaccine was developed by Jonas Salk (Killed vaccine) and by 1960, a second type of polio vaccine was developed by Albert Sabin (Live Vaccine, could be given orally).  Czechoslovakia was the first country in the world to eliminate polio.

·        In 1967, the World Health Organization announces the Intensified Smallpox Eradication Programme, to eradicate smallpox through surveillance and vaccination.

·        In 1969, Dr Baruch Blumberg and Irving Millman developed the first hepatitis B vaccine, by heat-treating the virus.

·        In 1971 the measles vaccine combined with vaccines against mumps and rubella into a single vaccination (MMR) by Dr Maurice Hilleman.

·        In 1974 the Expanded Programme on Immunization (EPI, now the Essential Programme on Immunization) was established by WHO to develop immunization programmes throughout the world. The first diseases targeted by the EPI are diphtheria, measles, polio, tetanus, tuberculosis and whooping cough.

·        In 1980 the WHO declared smallpox as eradicated.

·        In 1988, WHO launched Global Polio Eradication Initiative.

·        In 1999 the first vaccine against rotavirus was approved and a lower-risk version of the vaccine is introduced in 2006.

·        In 2006 the first vaccine for Human Papillomavirus (HPV) is approved.

·        On 2020, WHO declared COVID-19 as a pandemic.  Effective COVID-19 vaccines were developed, produced and distributed with unprecedented speed. In December 2020, just 1 year after the first case of COVID-19 was detected, the first COVID-19 vaccine doses are administered.

As per WHO Statistics, we now have vaccines to prevent more than 20 life-threatening diseases and these vaccines help people of all ages to live a longer and healthier life and prevents nearly 3.5 to 5 million deaths every year from diseases such as diphtheria, pertussis, tetanus, influenza and measles.

The principle of Vaccination is the exploitation of the extraordinary ability of our highly evolved immune system to respond to and remember their encounters with antigens.

A vaccine is a biological product that can be used to safely induce an immune response that confers protection against infection and/or disease on subsequent exposure to the corresponding pathogen. Vaccine contain antigens that are either derived from the pathogen or produced synthetically to represent components of the pathogen. The essential components of vaccines are one or more protein or polysaccharide antigens.

Types of Vaccines

Vaccines are generally classified as live or non-live (inactivated).  Live vaccines contain attenuated replicating strains of the relevant pathogenic organism and Nonlive or attenuated Vaccines contain killed whole organisms only components of a pathogen. In addition to these two classes, several new types have emerged recently such as those prepared based on viral vectors, nucleic acid-based RNA and DNA vaccines, virus-like particles, etc.

Live vaccines

Live vaccines contain live pathogens (either a bacteria or a virus) that have been "attenuated," or weakened. In an immunocompetent host they replicate sufficiently to produce a strong immune response, but not so much as to cause a significant disease.  Here the immune system reacts very well to vaccination and a very long time immunity results. Booster doses are not always needed.

Example are - vaccines for measles, mumps, rubella and rotavirus, oral polio vaccine, the Mycobacterium bovis bacillus Calmette–Guérin (BCG) vaccine for TB and live attenuated influenza vaccine.

Non-live vaccines

Non-live vaccines are killed whole organisms (whole-cell pertussis vaccine and inactivated polio vaccine) or purified proteins from the organism (acellular pertussis vaccine) or recombinant proteins (hepatitis B virus vaccine) or polysaccharides (pneumococcal vaccine against S. pneumoniae).  Toxoid vaccines are formaldehyde-inactivated protein toxins purified from the pathogen (tetanus and diphtheria).

Non-live vaccines are often combined with an adjuvant to improve their immunogenicity or ability to induce an immune response.  Examples of adjuvants are aluminium salts (alum) and oil-in-water emulsion

Subunit vaccines

Subunit vaccines are made from a piece of a pathogen. Some important subunit vaccines are polysaccharide vaccines, conjugate vaccines, and protein-based vaccines. Subunit vaccines can be made either from the original pathogen or by using recombinant technique.

Polysaccharide vaccines contain the capsular polysaccharides as the antigen and activate immune response against the respective pathogenic bacteria. Pneumococcal polysaccharide vaccine is an example.

A conjugate vaccine is a type of subunit vaccine in which a weak antigen is combined with a strong antigen as a carrier so that the immune system will produce a stronger response to the weak antigen. Examples are pneumococcal and meningococcal conjugate vaccines

Protein-based vaccines contain a specific protein from the surface of a virus or bacteria.  Example is the recombinant hepatitis B vaccine and Novavax COVID-19 vaccine.

Since Subunit vaccines contain only pieces or fragments from a pathogen, it does not cause disease, but only activates the immune system and thus they are suitable for children, older and immunocompromised individuals.

Recombinant vaccines are immunogenic proteins developed with the help of recombinant DNA technology. This involves inserting the DNA encoding the antigen into a host bacterial or mammalian cells, where the antigen will be expressed.  It could be isolated and purified and used as vaccine.  Examples: Vaccine against Hepatitis B, Influenza B and Meningitis.

Toxoid Vaccine

Toxoid is an inactivated toxin (usually an exotoxin) whose toxicity has been suppressed either by chemical or heat treatment, but the immunogenicity is maintained. Toxoid vaccines are effective and safe vaccines against diseases such as tetanus and diphtheria.

Viral vaccines and Bacterial vaccines

Viral vaccines contain either inactivated or attenuated viruses and bacterial vaccines contain either inactivated or attenuated bacteria.

Examples of viral vaccines are vaccines against Measles, Mumps, Rubella, Chickenpox, Polio, Influenza, Hepatitis A, Hepatitis B, Rabies, Rotavirus, Human papillomavirus, etc.

Examples of bacterial vaccines are vaccines against Diphtheria, Tetanus, Whooping cough, Meningitis, Pneumonia, Typhoid, Cholera, Plague, Anthrax, Tuberculosis, Tularemia, Typhus, etc

Different Types and Generations of Vaccines

Vaccines are divided to 3 generations based on the process of evolution

First-Generation Vaccines

Attenuated and inactivated vaccines are the first generation and known as traditional vaccine. Attenuated pathogens, full organisms or inactivated bacterial toxin are used in making these vaccines. Advantages are their high ability to stimulate innate immunity, induction of long-term protection, easy production, and low production costs. Disadvantages such as disease due to the use of complete pathogen (live or inactivated) and virulence reversal of the pathogen in the host.

Second-Generation Vaccines

Second-generation vaccines are based on subunit elements, recombinant or synthetic proteins, non-protein antigens, and expressed bacterial imunogene or viruses, which include numerous molecules and epitopes of different species and strains of pathogens. The subunit, conjugated, and recombinant vaccines are in this generation.

Third-Generation Vaccines

Immunogenic potential administration of a plasmid containing a gene encoding the antigen is the as third generation vaccines.  These are known as genetic vaccines, DNA vaccines, RNA vaccines, and plasmid vaccines.   These use engineered DNA or RNA to induce an immunologic response in the host against bacteria, parasites, viruses, cancer, etc

1st generation

Live attenuated vaccines

MMR, Influenza, OPV, Chickenpox, Yellow fever, Hepatitis A

Inactivated vaccines

Influenza, Hepatitis B, IPV, Rabies, Cholera, Plaque, Pertussis

2nd generation

Subunit vaccines

Hepatitis B, Diphtheria, Pertussis, Anthrax, Hemophilus Influenza B

Recombinant vaccines

Hepatitis B, HSV, Rota virus, HPV, FMD

3rd generation

DNA vaccines

HIV, Malaria, Cancer, Influenza, Ebola, Hepatitis, HPV

 

Different routes of administration of vaccines

Route of administration is the way by which a drug is taken into the body.  They are generally classified by the location in body where the drug is applied. Common routes of administration include topical (local), oral (enteral, delivered through the gastrointestinal tract) and parenteral (any route that is not enteral - intravenous (IV), intramuscular (IM), subcutaneous (SC) and intradermal (ID)).

Oral Route (PO)

Oral vaccine is administered through drops to the mouth. Rotavirus vaccine and Oral Polio Vaccine are administered orally. These should never be injected.  Oral vaccines activate immune cells in the mucousal membranes lining the gastrointestinal tract which is beneficial in protecting against diseases that affect the gut.

Intranasal Route (NAS)

Intranasal vaccine is administered into nostril using a nasal sprayer. Live, attenuated influenza Vaccine is administered by the intranasal route.

Subcutaneous Route (Subcut)

Subcutaneous injections are administered into the fatty tissue found below the dermis and above muscle tissue.  Vaccines given through subcutaneous administration are absorbed at a slower and constant rate as there is less blood supply in subcutaneous tissue.

Intramuscular Route (IM)

Intramuscular injections are administered into the muscle through the skin and subcutaneous tissue.   Since Muscle contains several blood vessels, the vaccine disperse easily. In addition, muscles contain dendritic cells that initiate a long-lasting immune response. Intramuscular vaccines tend to have fewer side-effects other than redness and pain at the injection site.

Intradermal (ID) Route (ID)

The injection is administered just below the skin or the dermal layer of the skin.  The epidermal and dermal layers of skin contain many antigen-presenting cells that play a significant role in mediating an efficient and protective immune response to vaccines.

Each vaccine has a recommended administration route and site. Any deviation from the recommended route may reduce vaccine efficacy or increase local adverse reactions.  Health care personnel should always perform proper hand hygiene before administering vaccines.

Except bacille Calmette-Guérin (BCG) vaccine and smallpox vaccine (these are administered by the percutaneous route), all other injectable vaccines are administered by the intramuscular or subcutaneous route.

Booster dose

A booster dose is extra administration of a vaccine after first or primer dose. It provides re-exposure to the antigen and help to increase immunity against that antigen back to protective levels if it has declined through time. For example, tetanus shot boosters are often recommended every 10 years, since by that time the memory cells specific against tetanus lose their function or undergo apoptosis.

Vaccine Components

·        Antigen - The active component of the vaccine that causes an immune response.

·        Adjuvants - enhances the effectiveness of vaccine. Most vaccines use aluminum-based adjuvants. They induce a range of inflammatory factors to the injection site which helps the immune response.

·        Preservatives - stop unwanted contamination of a vaccine. The most common preservative is 2-phenoxyethanol.  Thimerosal is a mercury-containing preservative used in multi-dose vaccines to prevent contamination of virulent bacteria or fungus.

·        Stabilizers - Stabilizers, such as gelatin, stop chemical reactions in the vaccine and prevent the components from separating. Other stabilizers include amino acids, potassium, sodium, and lactose.

·        Buffers - Buffers keep the vaccine at a similar pH to the body.

·        Adjusting tonicity - To keep the vaccine isotonic to reduce local reactions, often Sodium Chloride is added.

·        Surfactants and emulsifiers - These agents act like a detergent. A commonly used surfactant is called Polysorbate 80 or Tween®.  

·        Formaldehyde - Formaldehyde is used to detoxify or inactivate bacteria or toxin used in some vaccines.

·        Antibiotics - to prevent bacterial growth during storage of the vaccine.

BCG

BCG or Bacille Calmette-Guerin is the only vaccine against tuberculosis.  It is named after its inventors Albert Calmette and Camille Guérin.  Mycobacterium tuberculosis is the ethiological agent of tuberculosis (TB).  TB is a leading cause of human disease and death, particularly in developing countries.  One dose of BCG is recommended in healthy babies as soon as possible immediately after birth.

The vaccine is given intradermally and often redness, swelling, and mild pain occur at the site of injection, a small ulcer may also form where some scarring will be left after healing.  BCG vaccination can cause a false positive Mantoux test.

OPV and IPV

There is no cure for polio or poliomyelitis caused by Polio Virus, but it can be prevented with safe and effective vaccination. Poliomyelitis is a crippling disease that results from infection with any one of the three related poliovirus types (referred to as types P1, P2, and P3), members of the enterovirus (picornavirus) family. Poliovirus is transmitted from one person to another by oral contact with secretions or faecal material from an infected person.  

Polio vaccine is to be given multiple times and it always protects a child for life. There are six different vaccines against polio

  • Inactivated polio vaccine (IPV) – protects against poliovirus types 1, 2, and 3
  • Trivalent oral polio vaccine (tOPV) – protects against poliovirus types 1, 2, and 3
  • Bivalent oral polio vaccine (bOPV) – protects against poliovirus types 1, and 3
  • Monovalent oral polio vaccines (mOPV1, mOPV2 and mOPV3) – protect against each individual type of poliovirus, respectively

Inactivated polio vaccine (IPV) - An inactivated polio vaccine (IPV) was developed by Dr. Jonas Salk in 1955.  IPV is produced from wild-type poliovirus strains of each serotype inactivated with formalin.  It can be administered alone or in combination with other vaccines (e.g., diphtheria, tetanus, pertussis, hepatitis B, and haemophilus influenza). Generally, three spaced doses are administered and in most countries a booster dose is added during late childhood. IPV has been used successfully in the polio eradication programs in a few countries. IPV provides serum immunity to all three types of poliovirus.

Oral polio vaccine (OPV) - A live attenuated oral polio vaccine (OPV) was developed by Dr. Albert Sabin in 1961.  OPV consists of a mixture of live attenuated poliovirus strains of three serotypes. Three or more spaced doses of OPV are required. The action of OPV is two-pronged. OPV produces antibodies (humoral or serum immunity) against all three types of poliovirus and this protects the individual against polio paralysis by preventing the spread of poliovirus to the nervous system. OPV strain also produce a local immune response in the 'mucous membrane lining in the intestine (intestine is the primary site for poliovirus multiplication). The antibodies produced there inhibit the multiplication of subsequent infections with  polio.

In very rare cases, OPV results in vaccine-associated paralysis due to reversion of the vaccine strains to wild poliovirus.

DPT

DPT vaccine can prevent Diphtheria, Tetanus, and Pertussis (Whooping Cough).  The vaccine components are diphtheria and tetanus toxoids and either killed whole cells or antigen of the bacterium that causes pertussis.  If whole cells included, then vaccine is termed as "DTwP" and if acellular antigen is included, then termed as "DTaP".  DTP vaccine does not contain any live pathogen and therefore there is no risk of use.

WHO recommends the first dose be administered as early as 6 weeks of age and subsequent doses to be given 4-8 weeks apart, at age of 10-14 weeks and 14-18 weeks. A booster dose is to be given during the second year of life.

MMR

MMR vaccine was developed by Maurice Hilleman.  MMR vaccine can prevent measles, mumps, and rubella.  MMR vaccine is administered by a subcutaneous injection.  The first dose is generally given to children around 9 months to 15 months of age, with a second dose at 15 months to 6 years of age,

TAB

TAB vaccine is used against typhoid, TAB stands for Typhoid-paratyphoid A and B.  There are two vaccines. One is an un-conjugated polysaccharide vaccine given as a single dose and remain effective for 3 years. Other is conjugated polysaccharide typhoid vaccine which also is given as a single dose. The former can be administered after 2 years of age while the conjugate vaccine can be given from 6 months onwards.

Mission Indradhanush

Mission Indradhanush (MI) was launched by the Ministry of Health and Family Welfare (MoHFW), Govt of India on 25th December 2014.  It is a special campaign under the Universal Immunization Program (UIP), conducted to vaccinate all the children and pregnant women left out or dropped out from Routine Immunization.    Vaccination is being provided against eight vaccine-preventable diseases nationally, i.e. Diphtheria, Whooping Cough, Tetanus, Polio, Measles, severe form of Childhood Tuberculosis and Hepatitis B and meningitis & pneumonia caused by Haemophilus influenza type B and Rotavirus Diarrhea and Japanese Encephalitis.

Contraindications and Precautions to Vaccination

Contraindications and precautions to vaccination are situations when vaccines should not be administered.

A contraindication is a health condition in the recipient that increases the likelihood of a serious adverse reaction to a vaccine and vaccines should not be administered when a contraindication is present.

Medical conditions that are contraindications to vaccination include:

· A severe allergic reaction (e.g., anaphylaxis) to a vaccine component

· Severe immunosuppression is a contraindication to live, attenuated vaccines.

· A history of intussusception is a contraindication to rotavirus vaccination.

· Encephalopathy occurring within 7 days of pertussis vaccination is a contraindication to subsequent doses of pertussis-containing vaccine.

A precaution is a health condition in the recipient that might increase the chance or severity of a serious adverse reaction or might compromise the ability of vaccine to produce immunity. Problem could result, but the chance of happening is less than with a contraindication. Vaccines should be delayed when a a precaution is present.

Medical conditions that are precautions to vaccination include:

· Moderate or severe acute illness, with or without fever.

· History of thrombocytopenia is a precaution for MMR vaccine.

· Chronic gastrointestinal disease is precaution for rotavirus vaccine. 






(https://www.nature.com/articles/s41577-020-00479-7)