Deck 20: Antimicrobial Medications

A)penicillin.
B)ampicillin.
C)Salvarsan.
D)streptomycin.

A)penicillin.
B)sulfa.
C)erythromycin.
D)Salvarsan.

A)penicillin.
B)sulfa.
C)erythromycin.
D)Salvarsan.

A)Koch.
B)Hooke.
C)Fleming.
D)Ehrlich.

A)anti-metabolic.
B)catabolic.
C)synthetic.
D)semi-synthetic.

A)Koch.
B)Hooke.
C)Fleming.
D)Ehrlich.

A)-cidal.
B)-static.
C)-anti.
D)-genic.

A)selective toxicity.
B)biocide index.
C)biostatic index.
D)therapeutic index.

A)-cidal.
B)-static.
C)-anti.
D)-genic.

A)more toxic to the patient.
B)less toxic to the patient.
C)has no effect on the patient.
D)has no effect on the pathogen.

A)isolate usable.
B)stress-induced.
C)narrow-spectrum.
D)broad-spectrum.

A)metabolic destructive rate.
B)half-life.
C)effective time.
D)dosage rate.

A)antibiotics.
B)toxins.
C)inhibitors.
D)chemotherapy.

A)kill bacteria.
B)promote bacterial growth.
C)inactivate bacterial spores.
D)inhibit the growth of bacteria.

A)Penicillium
B)Streptomyces
C)Bacillus
D)Penicillium AND Streptomyces
E)All of the choices are correct.

A)penicillin.
B)sulfanilamide.
C)erythromycin.
D)Salvarsan.

A)insecticides.
B)biocides.
C)antiseptics.
D)antibiotics.

A)narrow-spectrum.
B)broad-spectrum.
C)targeted spectrum.
D)semi-synthetic.

A)energetic.
B)antagonistic.
C)subtractive.
D)synergistic.

A)allergic reactions.
B)toxic effects.
C)suppression of normal microbiota.
D)All of the choices are correct.

A)ribosomes.
B)penicillin-binding proteins.
C)peptidoglycan.
D)DNA gyrase.

A)infectious dose.
B)lethal dose.
C)effective dose.
D)minimum inhibitory concentration.

A)DNA gyrases.
B)LPS.
C)ribosomes.
D)PABA.

A)10%
B)50%
C)99.9%
D)100%

A)beta-lactam rings.
B)alpha-lactam rings.
C)phenolic rings.
D)sulfanilic rings.

A)primarily function in the cell to bind to beta-lactam drugs.
B)are enzymes.
C)are involved in cell wall synthesis.
D)inhibit non-growing bacteria.
E)are enzymes AND are involved in cell wall synthesis.

A)examples of metabolic inhibitors.
B)folate inhibitors.
C)protein synthesis inhibitors.
D)inhibitors of cell wall synthesis.
E)examples of metabolic inhibitors AND folate inhibitors.

A)S.aureus
B)S.epidermidis
C)M.luteus
D)Mycoplasma

A)peptidoglycan precursors.
B)penicillin-binding proteins.
C)ribosomes.
D)porin proteins.

A)aminoglycosides.
B)tetracyclines.
C)macrolides.
D)bacitracins.
E)aminoglycosides,tetracyclines,AND macrolides.

A)topoisomerases.
B)proteins.
C)DNA gyrases.
D)sulfonamides.
E)coenzymes.

A)bind to penicillin-binding proteins.
B)bind to peptides.
C)prevent the linking of glycan chains in peptidoglycan.
D)break the beta-lactam ring.

A)They are bacteriostatic.
B)They irreversibly bind to the 30S ribosomal subunit.
C)They block peptidoglycan synthesis.
D)They are bactericidal.
E)They irreversibly bind to the 30S ribosomal subunit AND they are bactericidal.

A)S.aureus.
B)S.epidermidis.
C)M.luteus.
D)M.tuberculosis.

A)MIC
B)MIB
C)MLB
D)Kirby-Bauer test

A)determines the concentration of antimicrobial necessary to kill a bacteria.
B)determines the concentration of antimicrobial necessary to inhibit growth of a bacteria.
C)is similar in principle to the Kirby-Bauer test.
D)determines the concentration of antimicrobial in a fluid.
E)is similar in principle to the Kirby-Bauer AND determines the concentration of antimicrobial in a fluid.

A)Penicillin
B)Cephalosporin
C)Vancomycin
D)Bacitracin
E)All of the choices are correct.

A)competitive inhibitors.
B)noncompetitive inhibitors.
C)ribosome-binding molecules.
D)feedback inhibitors.

A)antagonistic effect.
B)synergistic effect.
C)energetic effect.
D)subtractive.

A)In an example of a pediatric otitis media (middle ear)infection.We can't properly test for the specific drug that would best eliminate the infection due to its location,so we use a broad-spectrum drug instead.
B)In a case of viral meningitis.The infection spreads so quickly that we must treat it with an antibacterial drug as quickly as possible.We don't have time to determine which drug will work best,because the patient will die in the meantime.
C)In a case of bacterial meningitis.The infection spreads so quickly that we must treat it with an antibacterial drug as quickly as possible.We don't have time to determine which drug will work best,because the patient will die in the meantime.
D)In a case of Staphylococcus aureus skin infection.Since this microbe can be resistant to several types of drugs,we want to use one that has the broadest spectrum possible to treat this microbe-specific infection.

A)We want the largest possible number of choices of drugs in case a microbe shows resistance.With more possible weapons (even toxic ones),we have greater ability to eliminate infections.
B)Every person is different.What is toxic to one person may not be toxic to another person.To eliminate a useful drug because it's toxic to 1% of people treated is a waste.
C)Depending on the location of the infection,we may have no choice but to utilize a drug that has some toxic side effects to the patient.
D)They shouldn't be used.We have enough of a selection of drugs that we can always select a drug with no toxicity.Drugs with toxicity are simply leftovers-relics from a time when we didn't have as many drug options.

A)A test.
B)B test.
C)C test.
D)D test.
E)E test.

A)the ribosome.
B)nucleus.
C)cholesterol.
D)ergosterol.
E)cholesterol AND ergosterol.

A)binds to several sites on the target molecule.
B)targets several different molecules.
C)affects only one molecule.
D)affects the plasma membrane.
E)binds to several sites on the target molecule AND targets several different molecules.

A)size.
B)stability.
C)concentration.
D)All of the choices are correct.

A)drug-inactivating enzymes.
B)alteration in the target molecule.
C)decreased uptake of the drug.
D)increased elimination of the drug.
E)All of the choices are correct.

A)uncoating.
B)nucleic acid synthesis.
C)viral assembly.
D)viral ribosomes.
E)uncoating,nucleic acid synthesis,AND viral assembly.

A)viruses.
B)R plasmids.
C)introns.
D)exons.

A)Streptococcus.
B)Staphylococcus.
C)Mycobacterium.
D)Pseudomonas.

A)All drugs work synergistically with each other-that is,their combined effects are far greater than either could achieve individually.Two drugs together helps to eliminate microbes,even if they have developed spontaneous mutations that would confer upon them resistance to the drugs.
B)It is highly unlikely that the microbe might spontaneously develop two specific mutations to resist the effects of a pair of drugs.As such,even if one drug is resisted by the microbe,the second drug will eliminate the mutated microbe,thus preventing the development of spontaneously resistant mutants overall.
C)All drugs work antagonistically with each other-that is,their combined effects are far greater than either could achieve individually.Two drugs together helps to eliminate microbes,even if they have developed spontaneous mutations that would confer upon them resistance to the drugs.
D)Drugs can also select for mutations that will enhance the activity of another drug.So,each of the paired drugs will help to select for spontaneous mutations that enhance the activity of the other drug in the pair.

A)These drugs can only be taken up by cells that are infected by viruses.They are shut out from non-infected cells.This makes them effective only against cells where viruses are replicating.
B)Each of these drugs is specifically activated by enzymes produced by the viruses.The viruses will only produce these enzymes when they are replicating,so the drugs can only become activated when these processes are occurring.
C)Nucleoside analogs work by directly inhibiting the activity of nucleic acid polymerases.If the virus isn't actively replicating,there's no DNA/RNA polymerase active for the drug to inhibit,so the drug cannot work.
D)Nucleoside analogs work by being incorporated into growing strands of DNA/RNA.This indirectly shuts down further extension of these chains.However,new strands of viral DNA/RNA are only being created when the virus is replicating.As such,these drugs can only work when the virus is actively replicating as well.

A)Antibiotics only work within a narrow range of cell concentrations.If you use a concentration that is too low or too high,you will get inaccurate measurements of the zone of inhibition.
B)Antibiotic resistance is usually only manifested by bacteria that have achieved a very high concentration (i.e.,they are in the very end of the stationary phase of the growth curve).It's important to use bacteria specifically at this particular point for disc diffusion testing.
C)If you were to use one strain that was stationary phase (high concentration,replicating very slowly or not at all),and another strain that was just beginning log phase (low concentration but replicating quickly),you could see dramatically different results in the disc diffusion test.This could skew your interpretations of resistance/susceptibility.
D)Growth on the Mueller-Hinton agar plates utilized is very sensitive to the phase of the growth curve the bacteria are in when they are placed on the plate.If they are not in the log phase when they are placed on the plate,they will not grow and the test will be worthless.

A)Since most bacteriostatic drugs are produced from bacteria,but penicillin is produced from mold,the two drugs are incompatible with each other.
B)A bacteriostatic drug produces interference in the ability of a bacterial cell to take in compounds from the outside environment.Penicillin must be taken in by the cell in order to have its effect,so this would directly inhibit it.
C)Penicillin interferes with cell wall production/stabilization by cross-linking of peptidoglycan.As such,it only works when the cells are actively replicating and MAKING new peptidoglycan.A bacteriostatic drug works by shutting down replication,holding the cells "static." This would interfere with the mode of action required by the penicillin.
D)The bacteriostatic drugs would bind directly to the penicillin,preventing both its uptake by the cell and its ability to perform its duty within the bacterial cell.