ANTIMICROBIAL THERAPY

1. ANTIMICROBIAL THERAPY CHAPTER 13

2. Chemotherapeutic Agents • Antibiotics: bacteriocidal vs bacteriostatic • Synthetic Drugs vs natural product

3. History • Ancient remedies • Ehrlich • Domagk • Fleming

4. Properties of Antimicrobial Agents • Selective Toxicity • Spectrum of Activity • Narrow • Broad

5. Spectrum of Activity

6. Drug Mechanisms of Action • Inhibition of Cell Wall Synthesis • Disruption of Cell Membrane Function

7. Drug Mechanisms of Action • Inhibition of Protein Synthesis • Inhibition of Nucleic Acid Synthesis • Antimetabolites

8. Summary of Targets

9. Side Effects • Toxicity • Allergy • Disruption of Microflora

10. Classes of antibiotics • Aminoglycosides • Tetracyclines • Sulfonamides • Quinolones • Polypeptides • B-lactams • Macrolides • Glycopeptides • Cephalosporins

11. aminoglycosides kanamycin, neomycin, amikacin Binds 30 S ribosome

12. tetracyclines Tetracycline, Doxycycline Binds 30 S ribosome

13. sulfanamides Sulfacetamide Trimethoprim Sulfamethizole Folate synthesis inhibition. They are competitive inhibitors of the enzyme

14. B-lactams Amoxicillin Carbenicillin Penicillin Ampicillin disrupt the synthesis of the peptidoglycan layer of bacterial cell walls.

15. quinolones inhibit the bacterial DNA gyrase or the topoisomerase IV enzyme

16. polypeptides Inhibits isoprenyl pyrophosphate bacitracin Polymyxin B Interacts with the bacterial cytoplasmic membrane, changing its permeability.

17. macrolides Azithromycin Clarithromycin Spectinomycin Erythromycin Binds to 50s ribosome

18. Glycopeptides Vancomycin- last resort drug inhibiting peptidoglycan synthesis

19. cephalosporins Cefaclor Cefalexin Ceftobiprole Cefotaxime Same mode of action as other beta-lactam antibiotics: disrupt the synthesis of the peptidoglycan layer of bacterial cell walls.

20. Resistance to Drugs • Chromosomal - Klebsiella B lactamases • Plasmid borne - ribosomal protein mutations

21. Mechanisms of Drug Resistance • Mutations in Target molecules • Alterations in membrane permeability • Enzyme development

22. Fig. 27-27 Phosphorylation -Lactamase Adenylation Penicillin Streptomycin Acetylation Chloramphenicol

23. Table 27-7

24. Mechanisms of Drug Resistance • Enzyme Activity Changes • Alterations in Anabolic Pathways

25. Generations of Drugs • First/Second/Third Line Drugs • Cross Resistance

27. Limiting Drug Resistance • Effective Drug Concentrations • Simultaneous Drug Administration • Synergism - clavulanic acid • Antagonism - • Restricting Drug Prescriptions

28. Determining Microbial Sensitivities • Disk Diffusion Method • Dilution Method • Serum Killing Power • Automated Methods

29. Solubility Selective toxicity Stable toxicity level Allergenicity Tissue stability Resistance Acquisition Shelf Life Cost Ideal Antimicrobial Attributes

30. Antibacterials — Cell Wall Target • Penicillins

31. Antibacterials — Cell Wall Target • Cephalosporins • Carbapenems

32. Antibacterials — Cell Membrane Target • Polymyxins

33. Antibacterials — Protein Synthesis Inhibition • Aminoglycosides • Tetracyclines • Chloramphenicol • Macrolides Insert Fig. 13.13

34. Antibacterials — Nucleic Acid Synthesis Inhibition • Rifampin • Quinolones

35. Antibacterials — Antimetabolites • Sulfonamides • Isoniazid • Ethambutol • Nitrofurans

36. Antifungals • Imidazoles • Polyenes • Griseofulvin

37. Antifungals • Flucytosine • Tolnaftate • Terbinafine

38. Antivirals • Nucleotide analogs

39. Antivirals • Amantidine/Rimantidine • Interferons/Immunoenhancers

40. Antiprotozoan Drugs • Quinine/derivatives • Metronidazole • Pyrimethamine • Suramin

41. Antihelminthic Drugs • Niclosamide • Mebendazole • Ivermectin

42. Special Drug Resistance Problems