10.08 Chapter Summary

Overview of Infectious Diseases

Definition

• Infectious Diseases are illnesses caused by pathogens (microorganisms such as bacteria, viruses, protoctists, or fungi) that can be transmissible from one individual to another.

Key Characteristics

• Pathogen: The causative agent (bacteria, viruses, protoctists, etc.).
• Transmission: Mechanisms by which pathogens spread (direct contact, vectors, etc.).
• Impact Factors: Biological, social, and economic aspects influencing prevention and control.

Pathogens and Their Diseases

Cholera

• Pathogen: Vibrio cholerae (Bacterium)
• Type: Gram-negative, comma-shaped bacterium

Malaria

• Pathogen: Plasmodium species (Protoctists)
  • Plasmodium falciparum
  • Plasmodium malariae
  • Plasmodium ovale
  • Plasmodium vivax

Tuberculosis (TB)

• Pathogen:
  • Mycobacterium tuberculosis (Bacterium)
  • Mycobacterium bovis (Bacterium)

HIV/AIDS

• Pathogen: Human Immunodeficiency Virus (HIV) (Virus)
• Type: Retrovirus

Cholera

• Transmission Methods:
  • Fecal-Oral Route: Ingestion of contaminated water or food.
  • Contaminated Water Sources: Especially in areas with poor sanitation.

Malaria

• Transmission Methods:
  • Vector-Borne: Through the bite of infected Anopheles mosquitoes.
  • Blood Transmission: Rarely through blood transfusions or shared needles.

Tuberculosis (TB)

• Transmission Methods:
  • Airborne Droplets: Inhalation of droplets expelled when an infected person coughs or sneezes.
  • Close Contact: Living or working in close proximity to an infected individual.

HIV/AIDS

Transmission Methods:

• Blood Contact: Through sharing needles or blood transfusions with infected blood.
• Sexual Contact: Unprotected sexual intercourse with an infected person.
• Mother-to-Child: During childbirth or breastfeeding.

Biological Factors

• Pathogen Characteristics: Understanding virulence, resistance, and life cycle.
• Vaccination: Availability and effectiveness of vaccines (e.g., TB vaccine – BCG).
• Antimicrobial Treatments: Use of antibiotics (for bacterial infections) or antiretrovirals (for HIV).

Social Factors

• Public Awareness: Education on transmission and prevention methods.
• Healthcare Access: Availability of medical facilities and treatments.
• Cultural Practices: Influences on behaviors related to hygiene and healthcare seeking.

Economic Factors

• Resource Allocation: Funding for healthcare infrastructure and disease control programs.
• Economic Stability: Impact of poverty on access to clean water, sanitation, and medical care.
• Employment: Jobs related to healthcare provision and disease management.

Disease-Specific Prevention and Control Strategies

Cholera

• Biological:
  • Sanitation: Ensuring clean water supplies and proper sewage systems.
  • Vaccination: Oral cholera vaccines for high-risk areas.
• Social:
  • Hygiene Education: Promoting handwashing and safe food practices.
• Economic:
  • Infrastructure Investment: Building and maintaining water treatment facilities.

Malaria

• Biological:
  • Insecticides: Use of insecticide-treated bed nets (ITNs) and indoor residual spraying (IRS).
  • Antimalarial Drugs: Prophylaxis and treatment (e.g., artemisinin-based therapies).
• Social:
  • Community Engagement: Involving communities in prevention efforts.
• Economic:
  • Funding for Vector Control: Supporting mosquito control programs.

Tuberculosis (TB)

• Biological:
  • Antibiotic Therapy: Long-term use of multiple antibiotics to prevent resistance.
  • Vaccination: BCG vaccine in high-risk populations.
• Social:
  • Isolation of Infected Individuals: Preventing spread in healthcare settings.
  • Public Health Campaigns: Raising awareness about TB symptoms and treatment.
• Economic:
  • Healthcare Funding: Ensuring access to diagnostic and treatment services.

HIV/AIDS

Biological:

• Antiretroviral Therapy (ART): Managing HIV infection and preventing progression to AIDS.
• Prevention of Mother-to-Child Transmission: Providing ART during pregnancy and breastfeeding.

Social:

• Stigma Reduction: Combating discrimination against infected individuals.
• Education on Safe Practices: Promoting condom use and safe needle practices.

Economic:

• Access to Medications: Ensuring affordability and availability of ART.
• Support Services: Providing economic support to affected individuals and communities.

• Bactericidal Action: Penicillin effectively kills bacteria by causing cell lysis, rather than merely inhibiting their growth.
• Target: Penicillin specifically targets bacterial cell walls, which are essential for maintaining cell integrity.

Key Enzyme Inhibition:

• Penicillin-Binding Proteins (PBPs): These enzymes are crucial for the synthesis of peptidoglycan, a major component of the bacterial cell wall.
• Inhibition Process: Penicillin binds to PBPs, blocking their ability to catalyze the cross-linking of peptidoglycan strands.

Resulting Effects:

• Weakened Cell Wall: Without proper cross-linking, the cell wall becomes structurally weak.
• Cell Lysis: The weakened cell wall cannot withstand osmotic pressure, leading to bursting (lysis) of the bacterial cell.

Structural Differences:

• Bacteria: Prokaryotic cells with cell walls, ribosomes, and metabolic machinery.
• Viruses: Non-living particles consisting of genetic material (DNA or RNA) enclosed in a protein coat; lack cellular structures.

Replication Mechanism:

• Bacteria: Can reproduce independently through binary fission, requiring their own cellular machinery.
• Viruses: Require host cells to replicate, hijacking the host’s cellular machinery for reproduction.

Target Specificity:

• Antibiotics (like Penicillin): Target specific bacterial structures or processes (e.g., cell wall synthesis) that do not exist in viruses.
• Lack of Effect: Since viruses do not possess cell walls or the specific targets of antibiotics, these drugs have no impact on viral replication or survival.

Ineffective Treatments:

• Therapeutic Failure: Infections become harder to treat as bacteria are no longer susceptible to existing antibiotics.

Increased Healthcare Costs:

• Longer Hospital Stays: Resistant infections often require more extended and expensive treatments.
• Need for Alternative Drugs: New or more potent antibiotics are typically costlier.

Higher Mortality Rates:

• Severe Infections: Resistant bacteria can lead to more severe illnesses and higher death rates.

Spread of Resistant Strains:

• Epidemiological Spread: Resistant bacteria can spread between individuals and communities, exacerbating public health issues.

Limited Treatment Options:

• Scarcity of Effective Antibiotics: As resistance grows, the arsenal of effective antibiotics diminishes, leading to potential medical crises.

• Prudent Use of Antibiotics:
  • Avoid Overprescription: Only prescribe antibiotics when necessary and appropriate.
  • Appropriate Selection: Choose the right antibiotic for the specific bacterial infection.
• Completing Prescribed Courses:
  • Prevent Survival of Resistant Bacteria: Ensuring patients complete their antibiotic courses reduces the chance of resistant strains developing.
• Reducing Unnecessary Prescriptions:
  • Limit Use for Viral Infections: Avoid prescribing antibiotics for conditions like the common cold or flu, which are viral.
• Infection Control Measures:
  • Hygiene Practices: Implementing strict hygiene protocols in healthcare settings to prevent the spread of resistant bacteria.
  • Isolation Procedures: Isolating patients with resistant infections to limit transmission.
• Development of New Antibiotics:
  • Research and Innovation: Invest in the discovery and development of new antibiotics to stay ahead of resistant strains.
• Public Education and Awareness:
  • Informing the Public: Educate about the dangers of antibiotic misuse and the importance of adherence to prescribed treatments.
• Global Surveillance:
  • Monitoring Resistance Patterns: Track antibiotic resistance trends to inform public health strategies and policy-making.
• Antibiotic Stewardship Programs:
  • Optimizing Antibiotic Use: Implement programs in healthcare settings to ensure antibiotics are used responsibly and effectively.

Key Takeaways:

• Penicillin disrupts bacterial cell wall synthesis, effectively killing bacteria, but antibiotics are ineffective against viruses due to fundamental biological differences.
• Antibiotic resistance poses significant threats to public health, including treatment failures and increased mortality.
• Mitigating antibiotic resistance requires a multifaceted approach involving responsible antibiotic use, infection control, public education, and ongoing research.