Deliberate attempt to provide, induce, or boost protective immune responses

Goal in any one individual is the prevention of disease (Prep for HIV-antiviral retrotherapy)

Goal of a population is the eradication of disease(eradicate small pox)

A major effect has been control of infectious diseases

Parenteral Route : elicits IgG--next to the GI route

Subcutaneous, Intramuscular, Intradermal--require a needle

Oral Route :elicits IgA-just as affective maybe more

Toxoid:1.toxins treated with or absorbed with aluminum salts to generate toxoids which are immunogenic but not toxic.; 2.example: tetanus and diphtheria toxoid vaccines. Only applicable to bacterial toxins. 3.Typically handled as exogenous antigens thus only induces antibodies (Al to make immunogenic but not toxic, tetanus, bacterial, exogenous, antibody creation)

Subunit:

1.isolate subunit from organism to be used as a vaccine; generally has good safety profile; purified from the organism or generated by recombinant DNA technology. 2.Example: acellular pertussis (whooping cough) antigens.  3.Typically handled as exogenous antigen so only antibodies produced (purified/recombinant attenuation, whooping cough, exogenous, antibodies)

Conjugate Polysaccharide:1.For some bacteria virulence is imparted by polysaccharide capsule (PC); therefore, vaccines directed against these PCs is desirable. PCs do not activate T helper cells; therefore protein conjugation with the PCs is needed to generate T helper cell responses to PCs. 2.Examples : Hib (Haemophilus influenzae b), pneumococcal vaccine, meningococcal vaccine.  3.Typically handled as exogenous antigens so usually only antibodies produced (dealing with encapsulated bacteria-specifically targeting capsule/protein conjugation to activate Th/menigococcal/exogenous/antibody)

Immunology:

Immune responses to new antigenic structures on tumors or their detection by immune methods can be used for 3 purposes:(1) Diagnosis or prognosis of cancer (2) prophylaxis against cancer (3) anti-cancer therapy

Surveillance:  1. Prevention of tumors by early destruction of abnormal cells.2. Evidence for immunosurveillance-- Many tumors contain lymphoid infiltrates and may indicate a favorable clinical course--phenomenon of spontaneous regression of tumors, which typically is not well understood--tumors are frequent in the neonatal period or in old age when immune function is underdeveloped or suppressed--tumors arise frequently in immature/immunosuppressed individuals.

Cell Mediated Immune Response :
1. Macrophages activated by T cell derived IFN gamma kill tumor cells by the same mechanisms they use to kill microbes (i.e via TNF alpha, lysozyme, oxygen radicals, etc).

2. NK cells kill tumors by the same mechanisms they use to kill virus infected cells

3. Cytotoxic T cells kill tumors in an Ag specific and MHC restricted manner

Evasion:

Main two: Lack or down-regulation of co-stimulatory molecules or MHC  on tumor cells-- 1.lack co-stimulatory B7 and other adhesion molecules.(production of immunosurpressive proteins or expression of inhibitory cell surface protiens)  2. Downregulation of MHC class I(mutation in MHC genes or genes needed to process antigen)

3. Loss of tumor antigen expression (Failure to produce tumor antigen)

Traits:Invade the host (enter)-Resist host protective responses (innate immunity and adaptive immunity)-Remain in a niche[where they live/colonize] (attach)-Gain access to nutrients and multiply-Transfer to another host (exit)-Ability to cause disease (virulence factors)

Entry:Skin, eyes, ears--Respiratory tract (nasopharynx)--Gastrointestinal Tract (mouth)--Urogenital tract--Trauma (anywhere)

Exposure:Ingestion,Inhalation(arasols),Trauma, Needle stick(IV drug or hospital), Arthropod Bite, Sexual transmission

Colonization:Overcolonization by one bacterial species of a normally non-sterile area: GI tract, external mucosa of GU tract, upper respiratory tract--caused by normal flora or introduction of an external pathogen

Colonization of normally sterile organs and tissues: blood, lymph, CNS, lower respiratory system, internal organs and tissues--new portal of entry (bite, trauma) or a change in natural barriers, defenses--Blood, lymph, phagocytes carry bacteria to sterile body sites

Each has a preferred site

Modified when one microbe takes over(antibiotics)

movement from one body system to another(e. coli in gut is normal but in urinary tract-UTI

Non-specific immune enhancers; functions partially through stimulation of innate immune system

Depot effect (concentrated for slow release)=Particle increase/Production of cytokines/Inflammatory response(good as an acute response)/Typically required with non-live vaccines 

Adjuvant Types-redirect the immune response Inorganic salts and Aluminum OH

Recombinant Vector:1. vaccinia virus which is a large pox virus can deliver proteins (i.e. vaccines) which are generated by specific genes which have been cloned into the vector 2. safety issues are a concern with these kinds of preparations; other vectors are based on adenoviruses and retroviruses (mouse); these vaccines can be considered to mimic live attenuated vaccines in inducing both antibody and CTL responses. 3. None currently clinically approved. 4. Typically handled as endogenous and exogenous antigens (Administer the entire vector that makes up the pathogen including what is needed to translate the gene-all exposed to different types of adenovirus-issue can have different responses)

Recombinant Protein: 1.generate protein from organism through recombinant DNA technology and use as vaccine; can be considered a type of subunit vaccine. 2.Example: hepatitis B surface antigen vaccine which is made in yeast, recombinant influenza vaccine. 3.Typically handled as exogenous antigen and therefore only generates antibody responses (purify the protien from the vector system--inject just the protien

1.TSAs are unique to cancerous cells and are not found on normal counterparts 2.TSAs unique to a given neoplasm arise through point mutations in DNA damaged by carcinogenic chemicals, UV, or X-irradiation or through expression of unique proteins from oncogenic viruses (HPV and Hep B are viruses that can cause cancer)

1.TAAs are found on both normal and neoplastic cells, but their expression is greatly increased on tumors. 2.oncofetal antigens :CEA (carcinoembryonic antigen): elevated in colon,pancreas 3.CA  AFP (alpha-feto protein): elevated in liver and testicular 

 1. Immunization against oncogenic viruses constitute the only true prophylactic cancer vaccine examples hepatitis B(liver cancer) and human papillomavirus vaccines(cervical carcinoma)

2. More difficult to develop a targeted vaccine against a tumor of non-viral origin because of the lack of a true non-viral tumor specific antigen.

3. Immune Stimulators/Strategies for Anti-Cancer Vaccines--

Immunostimulant: Sipuleucel-T--FDA approved in 2008 for metastatic hormone refractory prostate cancer.  Consists of patients’ dendritic cells fused to PAP (prostatic acid phosphatase) and a cytokine growth factor.--Extends life about 3-4 months

Cell-based approaches: In vitro activated LAK and TIL cells--2. Stimulate leukocytes (CTL and NK cells) in vitro with IL-2 and infuse into patients--3. TIL – tumor infiltrating lymphocytes – remove lymphocytes that infiltrate tumor cell mass, stimulate with growth factors and re-introduce into patients to reduce tumor burden

1. Respiratory/aerosols--what happens when you sneeze-aerosol particles stay suspended in air for a time-transmission from one respiratory tract to another-common cold, influenza, Tb

2. Fecal-oral: could be in food and water, big problem on cruises with something getting into water supply- norovirus, e. coli

3. Sexual: gonorrhea, herpes, chlamydia-most common bacterial infection around 2 million confirmed cases each year probably closer to 5 million because its a lot of times asymptomatic 

4. Arthropod-born-flees, ticks, lice--zika, malaria-only female transmits--takes blood from infected person and ends up transferring to next person it bites

5. Zoonotic with animal reserve:in animals but can be transferred to humans--rabies(bats, cats, racoons)

6. Zoonotic with animal reservoir and arthropod vector--goes from animal to arthropod to human--lyme disease, plague 

Passive:Temporary/Prevent disease after a known exposure/Protect immunosuppressed patient(cant give live to these patients)/Block action of bacterial toxins

Examples: Snake bite anti-venom(extremely toxic-patient would die before they developed an adaptive immune response)--passive transfer of Ig from mother to child through placenta, breast milk

Active: Delayed immunity but more permanent than passive--Prevent disease before a known exposure

Examples: Natural exposure to antigens from pathogens and vaccines--Vaccines

1.Treatment of disease by inducing, enhancing, suppressing immune response:

2. Activation immunotherapies - elicit or amplify an immune response

3. Suppression immunotherapies - reduce or suppress an immune response

4. Use of monoclonal antibodies

A.Blocking action of molecular targets: Can work antagonistically by binding a receptor to prevent activation--Can also bind the antigen and prevent activation

B.“Magic Bullet”: Compound with target specificity is coupled with various effector groups--Toxins, radionuclei, enzymes, DNA

1. Normal self protien=no response

Tumor antigens

2. Mutated self protein= immune response

3. Product of oncogene or mutated tumor supressor gene=Tc cell response

4. Overexpressed or aberrently expressed self protien=Tc cell response

5. Oncogenic Virus=Virus-antigen specific Tc cells

CD28, CTLA-4 and B7 Expression on Immune Cells

CD28 is on resting and activated T cells--CTLA-4  is undetectable on resting T cells and is expressed on activated T cells--B7 molecules on dendritic cells, activated macrophages and activated B cells

We target CTLA-4 as a point for cancer therapy--want to up regulate immune response so we want to inhibit the inhibitor so that CTLA-4 does not turn off immune response

Can be direct toxin or indirect-must use factor to establish/colonize

Mechanisms and products used by bacteria to invade and colonize; bacterial by-products of living cause damage to the host, examples: enzymes, acids, gases

Many bacteria cause disease by directly destroying host tissue

Many bacteria release enzymes or toxins that inhibit host functions or destroy host tissue (bacteria may or may not be present in host)

Many different kinds and types of virulence factors