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<div> <ul> <li><a href="#introduction">Introduction to antimicrobials</a></li> <li><a href="#antifungals">Antifungal Drugs</a></li> <li><a href="#antiprotozoals">Antiprotozoal Drugs</a></li> <li><a href="#antihelminthics">Antihelminthic Drugs</a></li> <li><a href="#antibacterials">Antibacterials</a></li> <li><a href="#aminoglycosides">Aminoglycosides</a></li> <li><a href="#antifolates">Antifolate Drugs</a></li> <li><a href="#fluoroquinolones">Fluoroquinolones</a></li> <li><a href="#antimycobacterials">Antimycobacterial Drugs</a></li> </ul> <div id="introduction"> Viruses: Smallest pathogens, programmed to infect only certain body cells. Virus uses a body cells to reproduce itself it cannot be treated with medication. Bacteria: single celled microorganism, 1000 different bacteria, but 100 cause disease. - Bacteria can be treated with antibiotics. - Some bacteria are becoming immune to certain antibiotics. - Bacterial Diseases: Strep throat, Tuberculosis Gonorrhea, Syphilis Fungi: single celled or multicellular plantlike organism - Fungi can cause diseases of the skin, mucous membrane, and lungs. - Fungi Diseases: Athlete’s foot, Ringworm, Jock itch, Nail infections, Candidiasis</div> <div id="antifungals"> Amphotericin B continues to be an important drug for the treatment of systemic fungal infections. However, several azoles and echinocandins are proving to be just as effective in some systemic mycoses with less risk of toxic effects. </div> <div id="antiprotozoals"> Drugs for Malaria: Malaria is one of the most common diseases worldwide and a leading cause of death. Plasmodium species that infect humans (P falciparum, P malariae, P ovale, P vivax) undergo a primary developmental stage in the liver and then parasitize erythrocytes. P falciparum and P malariae have only 1 cycle of liver cell invasion. The other species have a dormant hepatic stage responsible for recurrent infections and relapses. Primary tissue schizonticides (eg, primaquine) kill schizonts in the liver, whereas blood schizonticides (eg, chloroquine, quinine) kill these parasitic forms only in the erythrocyte. Sporonticides (proguanil, pyrimethamine) prevent sporogony and multiplication in the mosquito. Drugs: Chloroquine, Quinine, Mefloquine, Primaquine, pyrimethamine, proguanil, Sulfadoxine, Dapsone, Doxycycline, Amodiaquine, Atovaquone, Halofantrine, Artesunate, Artemether, Dihydroartemisinin </div> <div id="antihelminthics"> Antihelminthic drugs have diverse chemical structures, mechanisms of action, and properties. Most were discovered by empiric screening methods; many act against specific parasites, and few are devoid of significant toxicity to host cells. In addition to the direct toxicity of the drugs, reactions to dead and dying parasites may cause serious toxicity in patients. </div> <div id="antibacterials"> Beta-Lactam Antibiotics & Other Cell Wall Synthesis Inhibitors Penicillins and cephalosporins are the major antibiotics that inhibit bacterial cell wall synthesis. They are called beta-lactams because of the unusual 4-member ring that is common to all their members. The beta-lactams include some of the most effective, widely used, and well-tolerated agents available for the treatment of microbial infections. Vancomycin, fosfomycin, and bacitracin also inhibit cell wall synthesis but are not nearly as important as the beta-lactam drugs. More than 50 antibiotics that act as cell wall synthesis inhibitors are currently available, with individual spectra of activity that afford a wide range of clinical applications. </div> <div id="aminoglycosides"> Aminoglycosides are structurally related amino sugars attached by glycosidic linkages. They are polar compounds, not absorbed after oral administration and must be given intramuscularly, or intravenously for systemic effect. They have limited tissue penetration and do not readily cross the blood-brain barrier. Glomerular filtration is the major mode of excretion, and plasma levels of these drugs are greatly affected by changes in renal function. Excretion of aminoglycosides is directly proportional to creatinine clearance. With normal renal function, the elimination half-life of aminoglycosides is 2–3 h. Dosage adjustments must be made in renal insufficiency to prevent toxic accumulation. Monitoring of plasma levels of aminoglycosides is important for safe and effective dosage selection and adjustment. For traditional dosing regimens (2 or 3 times daily), peak serum levels are measured 30–60 min after administration and trough levels just before the next dose. With once-daily dosing, peak levels are less important since they will naturally be high. </div> <div id="fluoroquinolones"> The fluoroquinolones interfere with bacterial DNA synthesis by inhibiting topoisomerase II (DNA gyrase), especially in gram-negative organisms and topoisomerase IV, especially in gram-positive organisms. They block the relaxation of supercoiled DNA that is catalyzed by DNA gyrase, a step required for normal transcription and duplication. Inhibition of topoisomerase IV by fluoroquinolones interferes with the separation of replicated chromosomal DNA during cell division. Fluoroquinolones are usually bactericidal against susceptible organisms. Like aminoglycosides, the fluoroquinolones exhibit postantibiotic effects, whereby bacterial growth continues to be inhibited even after the plasma concentration of the drug has fallen below the minimum inhibitory concentration of the bacterium </div> <div id="antimycobacterials"> Drugs for Tuberculosis The major drugs used in tuberculosis are isoniazid (INH), rifampin, ethambutol, pyrazinamide, and streptomycin. Actions of these agents on M tuberculosis are bactericidal or bacteriostatic depending on drug concentration and strain susceptibility. Appropriate drug treatment involves antibiotic susceptibility testing of mycobacterial isolates. Initiation of treatment of pulmonary tuberculosis usually involves a 3- or 4-drug combination regimen depending on the known or anticipated rate of resistance to isoniazid (INH). Directly observed therapy (DOT) regimens are recommended in noncompliant patients and in drug-resistant tuberculosis. </div> </div>