Antibiotics vs antivirals; resistance (overview)

Antibiotics are powerful medicines that fight bacterial infections. They work by either killing bacteria or slowing their growth, allowing the body's immune system to clear the infection. It is crucial to understand that antibiotics are ineffective against viruses.

How Antibiotics Work:

Antibiotics target specific structures or processes in bacterial cells that are not present in human cells, thus minimising harm to the host. Common targets include:

• Cell wall synthesis: Many antibiotics, like penicillin, prevent bacteria from building strong cell walls, causing them to burst.
• Protein synthesis: Some antibiotics interfere with the bacterial ribosomes, stopping them from producing essential proteins.
• DNA replication/RNA transcription: Other antibiotics disrupt the genetic machinery of bacteria, preventing them from multiplying.
• Metabolic pathways: Certain antibiotics block specific metabolic processes vital for bacterial survival.

Antivirals are a class of drugs used specifically to treat viral infections. Unlike antibiotics, antivirals do not kill the virus directly, but rather interfere with its life cycle, preventing it from replicating and spreading within the host cells. This helps the immune system to control the infection.

How Antivirals Work:

Viruses are obligate intracellular parasites, meaning they must use host cell machinery to reproduce. Antivirals target various stages of the viral life cycle, including:

• Entry inhibitors: Prevent the virus from entering host cells.
• Reverse transcriptase inhibitors: Used for retroviruses (e.g., HIV) to block the conversion of viral RNA into DNA.
• Protease inhibitors: Block enzymes needed for the virus to assemble new viral particles.
• Neuraminidase inhibitors: Used for influenza, these prevent newly formed viruses from being released from the infected cell.

Understanding the fundamental differences between these two drug classes is paramount for appropriate medical treatment.

It is a common misconception that antibiotics can treat viral infections like the common cold or flu. This is incorrect and contributes significantly to antibiotic resistance.

Antimicrobial resistance (AMR) occurs when microorganisms (bacteria, viruses, fungi, and parasites) evolve and develop the ability to withstand the effects of antimicrobial drugs, making treatments ineffective. This is a major global health and development threat.

Causes of Resistance:

• Overuse and misuse of antibiotics/antivirals: Prescribing antibiotics for viral infections, not completing a full course of antibiotics, and using them in agriculture.
• Poor infection control: Lack of hygiene in hospitals and communities allows resistant strains to spread.
• Lack of new drugs: The development of new antibiotics and antivirals has slowed significantly.
• Natural selection: When a population of bacteria is exposed to an antibiotic, susceptible bacteria die, but naturally resistant ones survive and reproduce, passing on their resistance genes. This is an example of evolution by natural selection.

Consequences of Resistance:

• Treatment failures: Infections become harder or impossible to treat.
• Increased morbidity and mortality: Longer illnesses, more severe disease, and higher death rates.
• Higher healthcare costs: Due to longer hospital stays and more expensive alternative treatments.
• Threat to modern medicine: Routine surgeries, organ transplants, and cancer chemotherapy become riskier without effective antimicrobials.