Immunisation Protects Against Infectious Disease: A Review
Received: 02-Jul-2022 / Manuscript No. nnp-22-69978 / Editor assigned: 04-Jul-2022 / PreQC No. nnp-22-69978 / Reviewed: 18-Jul-2022 / QC No. nnp-22-69978 / Revised: 22-Jul-2022 / Manuscript No. nnp-22-69978 / Published Date: 29-Jul-2022 DOI: 10.4172/2572-4983.1000250
Abstract
The purpose of immunisation is to prevent people from getting sick. It helps to protect people against the complications of becoming ill, including developing chronic diseases, cancer, and death. Vaccines work by stimulating the body’s defence mechanisms to provide protection against infection and illness. These defence mechanisms are collectively referred to as the immune system. Vaccines mimic and sometimes improve the protective response normally mounted by the immune system after infection. The great advantage of immunisation over natural infections is that immunisation has a much lower risk of harmful outcomes.
Keywords
Immuno; Infection; Vaccine; Body
Introduction
The immune system is the body’s defence mechanism, protecting against invaders like bacteria and viruses to keep us healthy.Cells are the main building blocks of our body. Our immune system relies on many different types of cells, each playing an important role [1-3]. Many of these can be found in our bloodstream, especially white blood cells, which are the main component of the human immune system.White blood cells are strategically located throughout the body, not only in the bloodstream but in the lymph nodes, spleen, lungs, intestines and skin. This allows them to deal with pathogens wherever they enter the body.There are two main types of white blood cells: guardian cells responsible for innate immunity (your body’s first defence against pathogens) lymphocytes responsible for specific or ‘adaptive’ immunity (your body’s ability to remember pathogens and react quickly if reinfected) [4-5].Other blood cell types include red blood cells, which carry oxygen to our tissues, and platelets, which help our blood to clot. Innate immunity The skin and the lining of the lungs and intestine are the first line of defence against infection, forming a physical barrier for protection [6]. These tissues and the sentinal cells that live there form the innate immune system There are two types of lymphocytes: T cells and B cells. T cells respond to infections by releasing chemicals called cytokines, which trigger protective inflammation. T cells can also kill cells that have a pathogen, such as a virus, hidden inside them B cells, often with help from T cells, are involved in making antibodies. Antibodies are complex proteins that attach in a ‘lock-and-key’ fashion either to pathogens or to the toxins released by them.
Vaccination is disease-specific
Immune responses are very specific, and that is the reason we need to have a specific vaccine for each The immune system responds separately to each pathogen it encounters [7,8]. It cannot be ‘overloaded’ by giving the full range of currently available vaccines or by having multiple antigens in one vaccine.A healthy immune system can generate hundreds of millions of T and B cells, each of which targets one particular antigen. However, pathogens can sometimes overwhelm the immune response. Vaccines give the immune system a head start by allowing it to learn and remember what a pathogen looks like, providing valuable protection against aggressive pathogens.
Pre-formed antibodies provide immediate protection
It takes around 7–21 days after being vaccinated to generate an effective immune response in healthy individuals.Most vaccines work by switching on a person’s immune system to make the antibodies, cytokines and memory cells needed to protect against infection. However, this kind of active immune response takes 7–21 days to fully develop. Sometimes, in the case of overwhelming and dangerous infections, an unwell person may receive pre-formed antibodies as part of their medical treatment to prevent or combat the infection. These either come from healthy blood donors or are produced in a laboratory, as they can act much more quickly to help the person fight off the infection [9-10] This is known as ‘passive immunisation’. However, these antibodies don’t stay in the body for very long—it is better to make antibodies through being vaccinated wherever possible. (Figure 1)
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Citation: Jose R (2022) Immunisation Protects Against Infectious Disease: A Review. Neonat Pediatr Med 8: 250. DOI: 10.4172/2572-4983.1000250
Copyright: © 2022 Jose R. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
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