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Introduction of Immunology

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Presentation on theme: " Introduction of Immunology"— Presentation transcript:

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2 1st lecture

3 Introduction Immunology: The study of the body’s immune response, it is responsible for protection the body against diseases. The term immunity means protection from diseases e.g. resistance to re-infection. Immune system: It is a defense system that has evolved to protect animals from invading pathogenic microorganisms and cancers.

4 Tumor Microbes Immune system
Our environment contains large numbers of microbes. These can cause disease, and if they multiply unchecked they will eventually kill their host. So, the primary function of the immune system is to eliminate infectious agents and to minimize the damage they cause. Tumor Environment Antigens Host Ag I.R. Immune response Microbes Immune system

5 Functionally, an immune response can be divided into two related activities:
1. The immune system is able to recognize subtle chemical differences that distinguish one foreign pathogen from another. Furthermore, the system is also able to discriminate between foreign molecules and the body’s own cells and proteins.

6 Immune response The different types of the immune response fall into two categories: Innate (non-specific) immune response: It is the first line of defense against infection it does not alter on repeated exposure to a given infectious agent and it Reacts in the same manner with each pathogen. Adaptive (specific) immune response: It is a highly specific for a particular pathogen the immune response improves with each successive encounter with the same antigen. Thus, the two key feature of the adaptive immune response are the specificity and the memory. The major agent of adaptive immunity are lymphocyte and the antibodies and other molecules they produce.

7 N. Characteristics Innate Immunity Adaptive immunity 1. Presence Innate immunity is something already present in the body. Adaptive immunity is created in response to exposure to a foreign substance. 2. Specificity Non-Specific Specific 3. Response Fights any foreign invader Fight only specific infection 4. Rapid Slow (1-2 weeks) 6. Time span Once activated against a specific type of antigen, the immunity remains throughout the life. The span of developed immunity can be lifelong or short. 7. Inheritance Innate type of immunity is generally inherited from parents and passed to offspring. Adaptive immunity is not passed from the parents to offspring, hence it cannot be inherited. 8 Present at birth Develops during a person’s lifetime and can be short-lived. 9 Used Against For microbes Microbes and non-microbial substances called antigens 10 Memory No memory Long term memory 11 Anatomic and physiological barriers Skin, Mucous membranes, Temp, pH, chemicals, etc. Lymph nodes, spleen, mucosal associated lymphoid tissue. 12. Composition The innate immune system is composed of physical and chemical barriers, phagocytic leukocytes, dendritic cells, natural killer cells, and plasma proteins. Adaptive immune system is composed of B cells and T cells. 13 Example White blood cells fighting bacteria, causing redness and swelling, when you have a cut. Chickenpox vaccination so that we don’t get chickenpox because adaptive immunity system has remembered the foreign body.

8 Defenses exist at several levels of development and specificity.
First line defenses are inborn physical barriers such as skin. Second line defenses are non-specific, protective reactions in the fluid compartments such as phagocytosis. Third line defenses are aimed at a specific pathogen and give a long term form of protection that will come into play if that pathogen is ever encountered again.

9 acquired and specific inborn

10 Innate Immunity There are four types of defensive barriers :
Anatomical barriers Physiological barriers Phagocytic barriers Inflammatory barriers.

11 1st lecture The natural, inborn, nonspecific defenses that can be divided into physical, chemical, and genetic barriers that impede the entry of microbes at the site of first contact

12 Barriers at the Body’s Surface
1st lecture Barriers at the Body’s Surface In the skin Stratum corneum of the skin is composed of epithelial cells that have become compacted, cemented together, and impregnated with an insoluble protein, keratin. Sebaceous secretions have an antimicrobial effects The high lactic acid and electrolyte concentrations of sweat and the skin’s acidic pH and fatty acid content

13 Skin is an example of physical barrier
Combat microbes at dermis level Langerhans and other immune cells Compete with pathogenic Normal microbiota Protect hair follicles, sweat and sebaceous glands Toxic lipids, lysozyme Remove adherent pathogens Sloughing of surface cells Prevent colonization, keratin hard to degrade Dead, keratinized Prevent microbes growth Dry, acidic (pH 5.0) Function Defense

14 1st lecture Eye lacrimation flush the eye’s surface with tears and rid it of irritants. Specialized glands such as the meibomian glands of the eyelids lubricate the conjunctiva with an antimicrobial secretion (lysozyme)

15 1st lecture The digestive tract The mucocutaneous membranes of the free surface of digestive tract. Saliva HCl the intestine’s digestive juices and bile. Vomiting and defecation

16 The genitourinary tract
The mucocutaneous membranes. Periodic bladder emptying and continuous trickle of urine through the ureters that flushes the urethra. Semen contains an antimicrobial chemical that inhibits bacteria. the vagina has a protective acidic pH maintained by normal flora.

17 Respiratory tract effective adaptations
1st lecture Respiratory tract effective adaptations Nasal hair Flushing action and copious flow of mucus and fluids that occurs in allergy and colds. The ciliated epithelium Irritation of the nasal passage reflexly initiates a sneeze, which expels a large volume of air at high velocity. The acute sensitivity of the bronchi, trachea, and larynx to foreign matter triggers coughing, which ejects irritants

18 Some pathogens have a great specificity to infect one host species that they are incapable of infecting other species ( e.g. Humans can’t acquire distemper from cats, and cats can’t get mumps from humans) Genetic differences in susceptibility can also exist within members of one species.

19 2. Physiologic barriers The physiologic barriers that contribute to innate immunity include temperature, pH, and various soluble and cell associated molecules. For example: Chickens, for example, have innate immunity to anthrax because their high body temperature inhibits the growth of the bacteria. Gastric acidity is an innate physiologic barrier to infection because very few ingested microorganisms can survive the low pH of the stomach contents.

20 3. Phagocytic barrier The ingestion of extracellular particulate material by phagocytosis. Phagocytosis is one type of endocytosis, the general term for the uptake by a cell of material from its environment.

21 4. Inflammation represents a complex sequence of events that stimulates Immune responses
Tissue damage caused by a wound or by an invading pathogenic microorganism induces a complex sequence of events collectively known as the inflammatory response. a molecular component of a microbe, such as LPS, may trigger an inflammatory response via interaction with cell surface receptors. The end result of inflammation may be the marshalling of a specific immune response to the invasion or clearance of the invader by components of the innate immune system.

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23 Why the first line of defense alone is not sufficient to protect against infection ?

24 Adaptive Immunity Adaptive immunity is capable of recognizing and selectively eliminating specific foreign microorganisms and molecules (i.e., foreign antigens). Adaptive immunity displays four characteristic attributes: Antigenic specificity of the immune system permits it to distinguish subtle differences among antigens. Antibodies can distinguish between two protein molecules that differ in only a single amino acid. Diversity: The immune system is capable of generating tremendous diversity in its recognition molecules, allowing it to recognize billions of unique structures on foreign antigens.

25 3. Immunologic memory: a second encounter with the same antigen induces a heightened state of immune reactivity. 4. Self/non self recognition: the immune system normally responds only to foreign antigens, indicating that it is capable of self/nonself recognition.

26 THANK YOU


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