Antimicrobial Pharmacology BCSE Study Guide

Overview and Clinical Importance

Antimicrobial pharmacology is fundamental to veterinary practice and represents a significant portion of Domain 2 on the BCSE examination (28-32 questions total for Pharmacology, Physiology, and Toxicology combined). This study guide covers all major antimicrobial classes including antibacterials, antifungals, antiparasitics, and antivirals.

Understanding mechanisms of action, spectrum of activity, pharmacokinetics, adverse effects, and species-specific considerations is essential for both examination success and clinical competency as an entry-level veterinarian.

High-YieldFocus on TIME-DEPENDENT vs CONCENTRATION-DEPENDENT killing for antibiotics. Beta-lactams are time-dependent (maximize time above MIC). Aminoglycosides and fluoroquinolones are concentration-dependent (maximize peak concentration).

Category	Examples	Spectrum and Clinical Use
Natural Penicillins	Penicillin G, Penicillin V	Gram-positive cocci (Streptococcus). Susceptible to beta-lactamases. Penicillin G is parenteral; Penicillin V is oral.
Aminopenicillins	Ampicillin, Amoxicillin	Extended gram-negative spectrum (E. coli, Proteus). Still susceptible to beta-lactamases. Amoxicillin has better oral absorption.
Beta-lactamase Resistant	Oxacillin, Methicillin, Cloxacillin	Staphylococcal infections. Resistant to staphylococcal beta-lactamases. MRSA/MRSP are resistant due to altered PBPs.
Potentiated Penicillins	Amoxicillin-Clavulanate, Ampicillin-Sulbactam	Broad spectrum including beta-lactamase producers. Clavulanate and sulbactam are beta-lactamase inhibitors with no inherent antimicrobial activity.
Extended-Spectrum	Piperacillin, Ticarcillin	Pseudomonas coverage. Often combined with beta-lactamase inhibitors (piperacillin-tazobactam).

Section 1: Beta-Lactam Antibiotics

[Include Image: Figure 1. Beta-lactam ring structure and mechanism of cell wall synthesis inhibition] Source: https://commons.wikimedia.org/wiki/File:Beta-lactam_antibiotics_example_1.svg

Beta-lactams are the most widely used antimicrobials in veterinary medicine. They share a common four-membered beta-lactam ring structure that is essential for their bactericidal activity. This class includes penicillins, cephalosporins, and carbapenems.

Mechanism of Action

Beta-lactams inhibit bacterial cell wall synthesis by binding to penicillin-binding proteins (PBPs), which are transpeptidase enzymes essential for cross-linking peptidoglycan chains. This prevents proper cell wall formation, leading to osmotic instability and bacterial cell lysis. Beta-lactams are bactericidal and exhibit TIME-DEPENDENT killing, meaning efficacy depends on maintaining drug concentrations above the minimum inhibitory concentration (MIC) for extended periods.

MEMORY AID - BETA-LACTAM Mechanism

"PBP = Prevents Building Peptidoglycan" - Beta-lactams bind Penicillin-Binding Proteins to prevent cell wall synthesis.

Penicillins

High-YieldAmoxicillin-clavulanate is one of the most commonly prescribed antibiotics in small animal practice. Clavulanate has NO antimicrobial activity - it only inhibits beta-lactamases.

MEMORY AID - Penicillin Classes

"A POEM for Penicillins": A = Aminopenicillins (Ampicillin, Amoxicillin), P = Potentiated (with clavulanate), O = Oxacillin-type (anti-staphylococcal), E = Extended spectrum (Piperacillin), M = Mother of all = Natural penicillins (Pen G)

Cephalosporins

Cephalosporins are classified by generations, with increasing gram-negative coverage and decreasing gram-positive coverage as generations progress. Third-generation cephalosporins are considered critically important antimicrobials by WHO.

MEMORY AID - Cephalosporin Generations

"Gram-Positive Goes Away as Generations Go up": 1G = Best gram-positive; 3G/4G = Better gram-negative. Think of it as a see-saw: as one goes up, the other goes down.

High-YieldCefovecin (Convenia) has a 14-day duration of action due to high protein binding (greater than 98%). It is administered as a single SC injection but has prolonged withdrawal in food animals and is NOT approved for food animal use.

Carbapenems

Carbapenems (imipenem, meropenem) have the broadest spectrum of any beta-lactam class and are resistant to most beta-lactamases. They are reserved for severe, multi-drug resistant infections and are considered critically important antimicrobials. They require parenteral administration and are typically hospital-based drugs.

Beta-Lactam Resistance Mechanisms

Resistance to beta-lactams occurs through three main mechanisms: (1) Production of beta-lactamases that hydrolyze the beta-lactam ring, (2) Alteration of penicillin-binding proteins (e.g., MRSA/MRSP), and (3) Decreased permeability or increased efflux. Extended-spectrum beta-lactamases (ESBLs) and AmpC enzymes confer resistance to third-generation cephalosporins.

MEMORY AID - Beta-Lactam Resistance

"BEP" for resistance: B = Beta-lactamases (destroy drug), E = Efflux pumps (pump drug out), P = PBP changes (target modification)

Generation	Veterinary Examples	Spectrum and Key Points
First (1G)	Cephalexin, Cefazolin, Cefadroxil	Best gram-positive coverage. Good for skin and soft tissue infections. Cephalexin is oral; Cefazolin is parenteral (surgical prophylaxis).
Second (2G)	Cefoxitin, Cefuroxime	Improved gram-negative coverage. Cefoxitin has anaerobic activity. Less commonly used in veterinary medicine.
Third (3G)	Ceftiofur, Cefpodoxime, Cefovecin	Excellent gram-negative coverage. Ceftiofur is widely used in food animals. Cefovecin (Convenia) has 14-day duration in dogs and cats. CRITICALLY IMPORTANT - reserve for culture-guided use.
Fourth (4G)	Cefepime, Cefquinome	Broad spectrum including Pseudomonas. Enhanced stability against AmpC beta-lactamases. Limited veterinary use.

Section 2: Aminoglycosides

[Include Image: Figure 2. Aminoglycoside mechanism of action at bacterial ribosome] Source: https://commons.wikimedia.org/wiki/File:Aminoglycoside_mechanism.svg

Aminoglycosides are bactericidal antibiotics that inhibit protein synthesis by binding irreversibly to the 30S ribosomal subunit. They exhibit CONCENTRATION-DEPENDENT killing and have a significant post-antibiotic effect (PAE), meaning bacterial killing continues even after drug concentrations fall below the MIC.

Key Aminoglycosides

High-YieldAminoglycosides are INACTIVE against ANAEROBES because drug uptake requires oxygen-dependent transport. They also have poor activity in acidic or hypoxic environments (e.g., abscesses).

Dosing and Toxicity

Once-daily (extended interval) dosing is preferred for aminoglycosides because: (1) Concentration-dependent killing is optimized with high peak concentrations, (2) Post-antibiotic effect allows drug-free intervals, (3) Nephrotoxicity is reduced by allowing drug-free periods for renal tubular regeneration. The main toxicities are NEPHROTOXICITY (renal tubular damage) and OTOTOXICITY (vestibular and cochlear damage). Risk increases with prolonged therapy, concurrent nephrotoxins, and dehydration.

MEMORY AID - Aminoglycoside Toxicity

"Amino-GLYCO-sides are NOT sweet to the kidneys and ears" - Remember NEPHROTOXICITY and OTOTOXICITY. Also: "A Mean Nasty Group" = Aminoglycosides cause Nephro- and Oto-toxicity

Drug	Characteristics and Uses
Gentamicin	Most commonly used systemic aminoglycoside. Excellent gram-negative coverage including Pseudomonas. Used IV or IM. Nephrotoxic and ototoxic.
Amikacin	Broadest spectrum aminoglycoside. More resistant to bacterial inactivating enzymes. Reserved for resistant infections. More expensive than gentamicin.
Neomycin	Topical and oral use only (too nephrotoxic for systemic use). Used in otic preparations and for GI decontamination. Poorly absorbed orally.
Streptomycin	Historical importance. Used for leptospirosis in cattle. Combined with penicillin for synergistic effect against enterococci.
Tobramycin	Enhanced Pseudomonas activity. Commonly used in ophthalmic preparations.

Section 3: Fluoroquinolones

[Include Image: Figure 3. Fluoroquinolone inhibition of DNA gyrase and topoisomerase IV] Source: https://commons.wikimedia.org/wiki/File:DNA_gyrase.svg

Fluoroquinolones are synthetic bactericidal antibiotics that inhibit bacterial DNA gyrase (topoisomerase II) and topoisomerase IV, essential enzymes for DNA replication, transcription, and repair. They exhibit CONCENTRATION-DEPENDENT killing with a significant post-antibiotic effect.

Veterinary Fluoroquinolones

High-YieldENROFLOXACIN IS CONTRAINDICATED IN CATS AT HIGH DOSES due to irreversible retinal degeneration causing blindness. Maximum dose is 5 mg/kg/day. This is a frequently tested BCSE topic.

Spectrum and Resistance

Fluoroquinolones have excellent gram-negative coverage including Pseudomonas (variable), good gram-positive coverage, and activity against Mycoplasma, Rickettsia, and Chlamydia. They are ineffective against most anaerobes (except pradofloxacin). Resistance develops through mutations in DNA gyrase (GyrA) or topoisomerase IV genes, and through efflux pumps.

MEMORY AID - Fluoroquinolone Toxicities

"CART" for FQ toxicities: C = Cartilage damage (growing animals), A = Arrhythmias (QT prolongation), R = Retinal toxicity (cats with enrofloxacin), T = Tendon problems (rare)

High-YieldFluoroquinolones cause CARTILAGE DAMAGE in growing animals. Avoid in puppies, kittens, and foals during rapid growth phases. The mechanism involves chelation of magnesium in cartilage.

Drug	Generation	Key Characteristics
Enrofloxacin	Second generation	Most commonly used veterinary fluoroquinolone. Broad gram-negative spectrum. CONTRAINDICATED in cats at doses greater than 5 mg/kg/day due to retinal toxicity.
Marbofloxacin	Second generation	Similar spectrum to enrofloxacin. Better safety profile in cats. Good tissue penetration.
Orbifloxacin	Second generation	Approved for dogs and cats. Similar spectrum to other second-generation agents.
Pradofloxacin	Third generation	Enhanced anaerobic coverage. Better activity against resistant organisms. Approved for cats.
Ciprofloxacin	Second generation	Human drug used off-label. Poor oral bioavailability in dogs and cats (approximately 40 percent or less). Better absorption in horses.

Section 4: Tetracyclines

Tetracyclines are broad-spectrum BACTERIOSTATIC antibiotics that inhibit protein synthesis by binding reversibly to the 30S ribosomal subunit, preventing attachment of aminoacyl-tRNA to the ribosome.

High-YieldDOXYCYCLINE is the drug of choice for tick-borne diseases (Ehrlichia, Anaplasma, Borrelia, Rickettsia). Unlike other tetracyclines, it is NOT significantly affected by concurrent food intake.

MEMORY AID - Tetracycline Absorption

"DOXY is Different" - Doxycycline absorption is NOT significantly affected by dairy/calcium unlike other tetracyclines. It is also eliminated hepatically (safe in renal disease).

Adverse Effects and Contraindications

Key adverse effects include: GI upset (common), photosensitivity, teeth discoloration in young animals (binds calcium), esophageal strictures in cats (give with water or food), and hepatotoxicity at high doses. Tetracyclines can cause fatal diarrhea in horses and disrupt rumen flora in adult ruminants. They are contraindicated in pregnancy due to fetal bone/teeth effects.

High-YieldALWAYS give doxycycline to cats with food or water to prevent esophageal stricture formation. Never dry-pill doxycycline in cats.

Drug	Half-life	Key Points
Doxycycline	Long-acting	Most lipophilic tetracycline. NOT significantly affected by food or dairy. Excellent tissue penetration. Drug of choice for tick-borne diseases (Ehrlichia, Anaplasma, Borrelia). Hepatic elimination - safe in renal failure.
Oxytetracycline	Short-acting	Commonly used in food animals. Long-acting injectable formulations available. Renal elimination. Binds calcium in developing teeth and bones.
Minocycline	Long-acting	Most lipophilic. Good CNS penetration. Can cause vestibular toxicity. Used for MRSP infections.
Chlortetracycline	Short-acting	Feed additive in food animals. Topical ophthalmic use.

Section 5: Macrolides and Lincosamides

Macrolides and lincosamides share a similar mechanism of action: both are BACTERIOSTATIC agents that inhibit protein synthesis by binding to the 50S ribosomal subunit. They share cross-resistance patterns known as MLSB (Macrolide-Lincosamide-Streptogramin B) resistance.

Macrolides

High-YieldTILMICOSIN IS FATAL IN HORSES, SWINE, AND GOATS due to cardiotoxicity. It is only approved for SC injection in cattle for BRD. Human injection can also be fatal.

MEMORY AID - Rhodococcus equi Treatment

"RAM" for R. equi: Rifampin + Azithromycin/clarithromycin (Macrolide). This combination is the mainstay treatment for R. equi pneumonia in foals.

Lincosamides

High-YieldCLINDAMYCIN is contraindicated in horses, rabbits, guinea pigs, hamsters, and chinchillas due to fatal antibiotic-associated diarrhea/pseudomembranous colitis.

MEMORY AID - Clindamycin Contraindications

"CHHRG" (sounds like CHIRP) - Clindamycin Harmful to Horses, Rabbits, Guinea pigs (and other hindgut fermenters)

Drug	Characteristics and Uses
Erythromycin	Prototype macrolide. Gram-positive spectrum. GI prokinetic effects. Commonly causes GI upset. Inactivated by gastric acid.
Azithromycin	Extended half-life due to tissue accumulation. Once-daily or less frequent dosing. Better tolerated than erythromycin. Good intracellular penetration.
Clarithromycin	Used with azithromycin for Rhodococcus equi in foals (combined with rifampin).
Tylosin	Veterinary-specific macrolide. Used in swine and poultry. Treatment of chronic enteropathies in dogs.
Tilmicosin	Long-acting injectable for bovine respiratory disease (BRD). CARDIOTOXIC - FATAL if injected into horses, goats, or swine. SC injection only in cattle.
Tulathromycin (Draxxin)	Single-dose treatment for BRD. Triamilide structure. Very long half-life.

Section 6: Sulfonamides and Potentiated Sulfonamides

[Include Image: Figure 4. Folate synthesis pathway and sites of sulfonamide and trimethoprim inhibition] Source: https://commons.wikimedia.org/wiki/File:Folate_synthesis_pathway.svg

Sulfonamides are synthetic BACTERIOSTATIC antibiotics that inhibit folic acid synthesis by competitively inhibiting dihydropteroate synthase, an enzyme that incorporates para-aminobenzoic acid (PABA) into the folic acid pathway. When combined with trimethoprim or ormetoprim (diaminopyrimidines), which inhibit dihydrofolate reductase, the combination becomes BACTERICIDAL through sequential blockade of the folate pathway.

MEMORY AID - Sulfonamide Mechanism

"PABA Problem" - Sulfonamides compete with PABA. Combined with Trimethoprim = "Two Steps of Folate Blocked = BACTERICIDAL"

Common Potentiated Sulfonamides

Trimethoprim-sulfamethoxazole (TMS) and trimethoprim-sulfadiazine are the most commonly used combinations. The typical ratio is 1:5 (trimethoprim:sulfonamide). These drugs have broad spectrum coverage including many gram-positive and gram-negative bacteria, some protozoa (Coccidia, Toxoplasma), and Nocardia.

High-YieldPotentiated sulfonamides are the treatment of choice for COCCIDIA (Isospora, Eimeria) and NOCARDIA infections.

Adverse Effects

Important adverse effects include: Keratoconjunctivitis sicca (KCS/dry eye) in dogs (may be irreversible), crystalluria (ensure adequate hydration), bone marrow suppression, hepatotoxicity, immune-mediated reactions (polyarthritis, skin eruptions), and thyroid suppression. Sulfonamides are contraindicated in Doberman Pinschers due to increased risk of immune-mediated reactions.

MEMORY AID - Sulfonamide Side Effects

"SULFA-DKBT" - Sulfonamides cause: D = Dry eye (KCS), K = Kidney crystals, B = Bone marrow suppression, T = Thyroid suppression

High-YieldSULFONAMIDES CAUSE KCS (dry eye) in dogs. This can be permanent. Recommend baseline Schirmer tear testing before long-term therapy.

Drug	Characteristics and Uses
Clindamycin	Excellent bone and dental penetration. Good anaerobic coverage. Used for osteomyelitis, dental infections, toxoplasmosis. Can cause fatal pseudomembranous colitis in horses, rabbits, and rodents.
Lincomycin	Parent compound. Less commonly used than clindamycin. Available in swine formulations.
Pirlimycin	Intramammary treatment of mastitis in dairy cattle.

Section 7: Antifungal Agents

[Include Image: Figure 5. Antifungal drug targets: cell membrane (azoles, polyenes) and cell wall (echinocandins)] Source: https://commons.wikimedia.org/wiki/File:Antifungal_targets.svg

Antifungal agents target unique components of fungal cells, primarily the cell membrane (ergosterol) and cell wall (beta-glucan). The three major classes used in veterinary medicine are azoles, polyenes, and echinocandins.

Azole Antifungals

Azoles inhibit lanosterol 14-alpha-demethylase (CYP51), a cytochrome P450 enzyme essential for ergosterol synthesis. Ergosterol is the main sterol in fungal cell membranes (analogous to cholesterol in mammalian cells). Azoles are FUNGISTATIC against most organisms.

High-YieldFLUCONAZOLE is the drug of choice for CRYPTOCOCCOSIS due to excellent CNS penetration. ITRACONAZOLE is preferred for BLASTOMYCOSIS and HISTOPLASMOSIS.

MEMORY AID - Azole Antifungals

"FIK-VP" = Fluconazole (CNS/Crypto), Itraconazole (Blasto/Histo), Ketoconazole (Cushings), Voriconazole (Aspergillus), Posaconazole (Mucor)

Polyene Antifungals

Polyenes (amphotericin B, nystatin) bind directly to ergosterol in the fungal cell membrane, creating pores that cause leakage of cellular contents. Amphotericin B is FUNGICIDAL with the broadest antifungal spectrum but is limited by significant NEPHROTOXICITY. Lipid formulations reduce nephrotoxicity but are expensive. Nystatin is too toxic for systemic use and is only used topically.

MEMORY AID - Amphotericin B Toxicity

"AmphoBterrible for Kidneys" - Amphotericin B causes significant nephrotoxicity. Pre-hydration with saline helps reduce toxicity.

Echinocandins

Echinocandins (caspofungin, micafungin, anidulafungin) inhibit beta-1,3-D-glucan synthase, preventing synthesis of the fungal cell wall. They are called the "penicillin of antifungals" because they target the cell wall like beta-lactams target bacterial cell walls. They are FUNGICIDAL against Candida and FUNGISTATIC against Aspergillus. Limited use in veterinary medicine due to IV-only administration and cost.

High-YieldEchinocandins target the CELL WALL (beta-glucan), not the cell membrane. This is a unique target not found in mammalian cells, resulting in excellent safety profiles.

Drug	Characteristics and Clinical Use
Fluconazole	Best CNS penetration of azoles. Drug of choice for Cryptococcus. Good for systemic candidiasis. Fewer drug interactions than other azoles.
Itraconazole	Broad spectrum including Blastomyces, Histoplasma, Aspergillus, Sporothrix. Requires acidic environment for absorption - give with food. Significant drug interactions (CYP3A4 inhibitor).
Ketoconazole	Oldest systemic azole. Significant hepatotoxicity and drug interactions. Also inhibits adrenal steroid synthesis - used for hyperadrenocorticism treatment.
Voriconazole	Enhanced Aspergillus activity. Used for resistant fungal infections. Available IV and oral.
Posaconazole	Broadest spectrum azole including Mucorales (zygomycosis). Limited veterinary data.

Section 8: Antiparasitic Agents

[Include Image: Figure 6. Mechanisms of action of major antiparasitic drug classes] Source: https://commons.wikimedia.org/wiki/File:Parasite_treatment.svg

Benzimidazoles

Benzimidazoles (fenbendazole, albendazole, mebendazole, oxfendazole) bind to parasite beta-tubulin, preventing microtubule polymerization. This disrupts glucose uptake and energy metabolism, leading to parasite starvation and death. They have broad spectrum activity against nematodes and some cestodes.

High-YieldFENBENDAZOLE is one of the safest anthelmintics with a wide margin of safety. ALBENDAZOLE is teratogenic and contraindicated in pregnant animals.

Macrocyclic Lactones (Avermectins and Milbemycins)

Macrocyclic lactones (ivermectin, selamectin, moxidectin, milbemycin) potentiate glutamate-gated chloride channels in invertebrate nerve and muscle cells, causing hyperpolarization, paralysis, and death. They are effective against nematodes and arthropods. These channels are not present in mammals, providing a high safety margin (except in animals with MDR1 mutations).

High-YieldMDR1 (ABCB1) MUTATION: Collies, Australian Shepherds, Shelties, and related breeds can have severe ivermectin toxicity (blindness, ataxia, coma, death) due to increased CNS drug penetration. Test before using high-dose ivermectin.

MEMORY AID - MDR1 Mutation Breeds

"White Feet, Don't Treat" (with high-dose ivermectin) - Collie-type breeds with white markings often carry MDR1 mutation. Better yet: "COLLIES" = Can Only tolerate Low Levels of Ivermectin-type Ectoparasiticides Safely

Other Antiparasitics

High-YieldPRAZIQUANTEL is the drug of choice for ALL cestodes (tapeworms) including Dipylidium caninum, Taenia, and Echinococcus.

MEMORY AID - Antiparasitic Drug Classes

"BIG MIP FP" - Benzimidazoles, Isoxazolines, avermectins (Glutamate channels), Macrocyclic lactones, Imidacloprid, Pyrantel, Fipronil, Praziquantel

Drug	Key Points
Fenbendazole	Very safe with wide margin of safety. Effective against roundworms, hookworms, whipworms, and Giardia. Commonly used in dogs, cats, and food animals. Multi-day dosing often required.
Albendazole	Broader spectrum than fenbendazole. TERATOGENIC - contraindicated in pregnancy. Can cause bone marrow suppression in dogs and cats.
Oxfendazole	Metabolite of fenbendazole. Used in cattle and horses.

Section 9: Antiviral Agents

Antiviral drugs are limited in veterinary medicine compared to antibacterials. Most target viral nucleic acid synthesis. Only a few antivirals are licensed for veterinary use, with many others used off-label from human medicine.

Nucleoside Analogues

High-YieldFAMCICLOVIR is the drug of choice for FHV-1 in cats. VALACYCLOVIR/ACYCLOVIR are TOXIC in cats and should NOT be used systemically.

MEMORY AID - Antiviral for Cats

"FAM is a Friend to Feline Herpes" - FAMciclovir is safe and effective for FHV-1. "ACYclovir is AWFULLY TOXIC in Cats"

Interferons

Feline interferon-omega (Virbagen Omega) is the only interferon licensed for veterinary use (in some countries). It has immunomodulatory and antiviral properties. It is used to reduce mortality in canine parvovirus and to improve clinical signs in cats with FeLV or FIV. Human recombinant interferon-alpha has also been used off-label.

High-YieldFELINE INTERFERON-OMEGA is licensed to reduce mortality in canine parvovirus and for supportive treatment of FeLV/FIV in cats.

Drug	Characteristics
Ivermectin	Broad spectrum nematocide and ectoparasiticide. Heartworm preventive. TOXIC in dogs with MDR1 (ABCB1) mutation (Collies, Shelties, Australian Shepherds). Used in many species.
Selamectin	Topical application. Heartworm, flea, ear mite, and some intestinal parasite prevention. Revolution brand.
Moxidectin	More lipophilic than ivermectin. Longer duration of action. Used in heartworm prevention (ProHeart) and treatment of demodectic mange.
Milbemycin oxime	Safer in MDR1-mutant dogs at heartworm preventive doses. Combined with other drugs in heartworm preventives.

Drug Class	Examples	Mechanism and Uses
Isoxazolines	Fluralaner, Afoxolaner, Sarolaner	Block insect GABA-gated chloride channels. Oral or topical flea and tick preventives. Long duration of action (1-3 months).
Pyrantel/Oxantel	Pyrantel pamoate	Nicotinic agonist causing spastic paralysis of nematodes. Safe, commonly used dewormer. Poor absorption - acts locally in GI tract.
Praziquantel	Praziquantel	Drug of choice for cestodes (tapeworms) and trematodes (flukes). Causes calcium influx and spastic paralysis.
Imidacloprid	Advantage	Nicotinic acetylcholine receptor agonist in insects. Topical flea adulticide. Often combined with other drugs.
Fipronil	Frontline	GABA receptor antagonist in insects. Topical flea and tick preventive. NOT for rabbits (toxic).

Drug	Mechanism and Veterinary Use
Famciclovir	Prodrug of penciclovir. Drug of choice for FELINE HERPESVIRUS-1 (FHV-1). Inhibits viral DNA polymerase. Safe in cats at 40-90 mg/kg PO q8-12h. Penciclovir has good activity against FHV-1.
Acyclovir	Inhibits herpesvirus DNA polymerase. Poor oral bioavailability and efficacy against FHV-1. TOXIC IN CATS (bone marrow suppression, nephrotoxicity). Used topically for equine herpesvirus.
Valacyclovir	Prodrug of acyclovir. CONTRAINDICATED IN CATS - causes severe toxicity. May be used in horses for EHV-1.
GS-441524/Remdesivir	Nucleoside analogue that inhibits viral RNA polymerase. Effective treatment for FELINE INFECTIOUS PERITONITIS (FIP). GS-441524 is the active metabolite of remdesivir.

Antimicrobial Pharmacology – BCSE Study Guide

Overview and Clinical Importance

Section 1: Beta-Lactam Antibiotics

Mechanism of Action

Penicillins

Cephalosporins

Carbapenems

Beta-Lactam Resistance Mechanisms

Section 2: Aminoglycosides

Key Aminoglycosides

Dosing and Toxicity

Section 3: Fluoroquinolones

Veterinary Fluoroquinolones

Spectrum and Resistance

Section 4: Tetracyclines

Adverse Effects and Contraindications

Section 5: Macrolides and Lincosamides

Macrolides

Lincosamides

Section 6: Sulfonamides and Potentiated Sulfonamides

Common Potentiated Sulfonamides

Adverse Effects

Section 7: Antifungal Agents

Azole Antifungals

Polyene Antifungals

Echinocandins

Section 8: Antiparasitic Agents

Benzimidazoles

Macrocyclic Lactones (Avermectins and Milbemycins)

Other Antiparasitics

Section 9: Antiviral Agents

Nucleoside Analogues

Interferons

Practice Questions

Ready to Practice for the BCSE?

Antimicrobial Pharmacology &ndash; BCSE Study Guide

Overview and Clinical Importance

Section 1: Beta-Lactam Antibiotics

Mechanism of Action

Penicillins

Cephalosporins

Carbapenems

Beta-Lactam Resistance Mechanisms

Section 2: Aminoglycosides

Key Aminoglycosides

Dosing and Toxicity

Section 3: Fluoroquinolones

Veterinary Fluoroquinolones

Spectrum and Resistance

Section 4: Tetracyclines

Adverse Effects and Contraindications

Section 5: Macrolides and Lincosamides

Macrolides

Lincosamides

Section 6: Sulfonamides and Potentiated Sulfonamides

Common Potentiated Sulfonamides

Adverse Effects

Section 7: Antifungal Agents

Azole Antifungals

Polyene Antifungals

Echinocandins

Section 8: Antiparasitic Agents

Benzimidazoles

Macrocyclic Lactones (Avermectins and Milbemycins)

Other Antiparasitics

Section 9: Antiviral Agents

Nucleoside Analogues

Interferons

Practice Questions

Related Articles

Ready to Practice for the BCSE?

Antimicrobial Pharmacology – BCSE Study Guide