Deck 4: Properties of Drugs

A) Absoprtion, metabolism, elimination, distribution
B) Distribution, elimination, metabolism, absorption
C) Elimination, distribution, metabolism, absorption
D) Absorption, distribution, metabolism, elimination

A) able to alter neurotransmission.
B) highly potent.
C) administered orally.
D) crosses the blood-brain barrier.

A) Nonspecific binding
B) Distribution
C) Active transport
D) Biotransformation

A) distribution
B) absorption
C) metabolism
D) elimination

A) Intramuscular
B) Oral
C) Inhalation
D) Sublingual

A) pKa.
B) administration
C) liberation.
D) passive diffusion.

A) allow pathogens normally blocked by the blood-brain barrier to enter the brain.
B) increase the activity of active transport mechanisms.
C) cause blood vessels to dilate, increasing cerebral blood flow.
D) cause endothelial cells to fit more tightly together.

A) Drug Y produced more ionized molecules than Drug Z
B) The administration route for Drug Y was more effective than Drug Z.
C) The pKa value of Drug Y was closer to 3 than the pKa of Drug Z.
D) The local environment had a large surface area

A) impact the amount of drug absorbed through passive diffusion.
B) change the pKa of a drug.
C) can alter the local pH.
D) can be calculated by the Henderson-Hasselbalch equation.

A) small
B) quickly metabolized
C) inhaled
D) non-ionized

A) intramuscular.
B) subcutaneous.
C) intravenous.
D) oral.

A) the drug entered the brain through active transport mechanisms.
B) the drug is synthesized and released from cells in the brain.
C) the properties of the substance were altered by brain glial cells.
D) nonspecific binding allowed the drug to pass through the blood-brain barrier.

A) require biotransformation before they can enter the brain.
B) are synthesized by neurons.
C) must enter the brain through active transport mechanisms.
D) are synthesized by glial cells.

A) the drug's pKa.
B) the drug's active transport through the blood-brain barrier.
C) the drug's bioavailability.
D) the amount of biotransformation that took place.

A) transdermal.
B) inhalation.
C) oral.
D) intravenous.

A) lipid soluble, charged, and relatively small.
B) water soluble, charged, and relatively small.
C) lipid soluble, uncharged, and relatively small.
D) water soluble, uncharged, and relatively large.

A) distribution.
B) absorption.
C) administration.
D) biotransformation

A) Neither will diffuse through membranes
B) Both Drug A and B equally
C) Drug B
D) Drug A

A) that nonspecific binding occurred.
B) the drug could enter the brain using active transport mechanisms.
C) the drug's pKa had matched the pH of the physiological medium it was administered in.
D) the drug was not small, non-charged or lipid soluble.

A) Develop a drug to block membrane transporters.
B) Develop a drug to increase catabolic enzyme activity.
C) Develop a drug to block calcium channels
D) Develop a drug to block postsynaptic receptors.

A) functioned as a prodrug.
B) underwent Phase II biotransformation.
C) acted in a conjugation reaction.
D) underwent first-pass metabolism.

A) Elimination
B) Biotransformation
C) Distribution
D) Absorption

A) Increased synthesis of the neurotransmitter
B) Increased storage of neurotransmitters in vesicles
C) Increased levels of the neurotransmitter in the synaptic cleft
D) Increased release of the neurotransmitter

A) Phase I biotransformation.
B) Phase II biotransformation.
C) nonspecific binding.
D) passive diffusion.

A) conjugation
B) biotransformation
C) first-pass metabolism
D) active transport

A) first-order kinetics.
B) second-order kinetics.
C) zero-order kinetics.
D) linear kinetics.

A) the prodrug is also an antidepressant drug.
B) the active metabolite could be likely be directly administered as an antidepressant drug.
C) the prodrug had acted like a placebo.
D) the prodrug was unable to cross the blood-brain barrier.

A) the drug's elimination rate is known.
B) the drug is eliminated by first-order kinetics.
C) the drug is administered regularly according to a set schedule.
D) the steady-state is linked to a particular level of drug effect.

A) the participant had taken an additional dose of the drug.
B) the drug's elimination rate follows first-order kinetics.
C) the drug's elimination rate follows zero-order kinetics.
D) the participant is a poor metabolizer.

A) 3 μEq/L
B) 0 μEq/L
C) 6 μEq/L
D) 2 μEq/L

A) nonspecific binding.
B) Phase II biotransformation.
C) Phase I biotransformation.
D) first-pass metabolism.

A) inhibits passage of dopamine through vesicular transporters.
B) inhibits reuptake of dopamine.
C) inhibits binding of dopamine to receptors.
D) inhibits synthesis of dopamine.

A) nonspecific binding rate.
B) elimination rate.
C) biotransformation rate.
D) ideal adminstration route.

A) Increase norepinephrine concentrations by increasing synthesis.
B) Reduce the amount of amount of norepinephrine released into the synaptic cleft.
C) Increase norepinephrine concentrations by preventing catabolism of norepinephrine.
D) Reduce norepinephrine release by affecting exocytosis.

A) producing inhibitory postsynaptic potentials.
B) destroying axon terminals.
C) blocking sodium channels.
D) preventing neurotransmitter reuptake.

A) eliminated by zero-order kinetics.
B) a non-active metabolite.
C) a placebo.
D) a prodrug.

A) she is not complying with the physician's instructions.
B) she has fewer enzymes capable of breaking down the drug.
C) the drug is unable to cross the blood-brain barrier.
D) the drug is nonspecifically binding to proteins in blood.

A) a polymorphism process.
B) nonspecific binding.
C) Phase I biotransformation.
D) Phase II biotransformation.

A) Develop a drug to block membrane transporters.
B) Develop a drug to increase neurotransmitter synthesis.
C) Develop a drug to block postsynaptic receptors.
D) Develop a drug to block autoreceptors.

A) partial agonist
B) negative modulator
C) agonist
D) antagonist

A) the drug will strongly activate the receptor.
B) the drug will outcompete drugs with lower affinities for the receptor.
C) the drug will strongly block the receptor.
D) the drug will large value for a dissociation constant.

A) prevent a neurotransmitter from activating a receptor.
B) prevent a neurotransmitter from binding to receptor.
C) bind to a site different from the neurotransmitter binding site.
D) fail to cause a conformation change in the receptor.

A) a G-protein repels away neurotransmitters.
B) neurotransmitters enter the neuron.
C) no effects occur for a G-protein.
D) a G-protein becomes activated.

A) antagonist
B) agonist
C) partial agonist
D) positive modulator

A) conducting an experiment to assess receptor efficacy.
B) conducting an experiment to determine if the drug is an allosteric modulator.
C) conducting a binding affinity experiment.
D) conducting a ternary receptor model experiment.

A) The drug will prevent activation of G-proteins
B) The drug will block neurotransmission
C) The drug will counteract the effects of an antagonist
D) The drug will weaken, but not prevent, neurotransmission

A) neurotransmitter.
B) receptor.
C) positive modulator.
D) positively charged ion.

A) a decreased reuptake of dopamine.
B) an increased concentration of dopamine in the synaptic cleft.
C) an increased synthesis of dopamine.
D) an inhibition of monoamine oxidase (MAO).

A) Drug A
B) Drug B
C) Drug C
D) Drug D

A) Binding affinity
B) Receptor efficacy
C) Dissociation constant
D) Bmax

A) prevents neurotransmission.
B) facilitates the effects of a neurotransmitter at receptors.
C) can activate receptors.
D) has a weak binding affinity for receptors.

A) only ligands with a high affinity for a receptor can activate a receptor.
B) a G-protein can prevent a ligand from binding to a receptor.
C) receptor actions depend on an interaction between a ligand, receptor, and G-protein.
D) receptor efficacy only pertains to metabotropic receptors.

A) the drug has a poor binding affinity for the receptor.
B) the drug will prevent a neurotransmitter from activating a receptor.
C) the drug will produce greater neurotransmitter release.
D) the neurotransmitter has a poor binding affinity for the receptor.

A) partial agonist
B) agonist
C) antagonist
D) allosteric regulator

A) the study compound is a mixture of agonists and antagonists.
B) behavioral or physiological responses will appear weaker than those produced by a full agonist.
C) the drug bound to some receptors but not others.
D) a G-protein will only be partly activated.

A) neurotransmitter synthesis will be reduced.
B) neurotransmitters escape the axon terminal.
C) neurotransmitters become catabolized by enzymes.
D) neurotransmitters concentration will increase in the synaptic cleft.

A) competitive antagonist
B) noncompetitive antagonist
C) partial agonist
D) negative modulator

A) some of the receptors the drug binded to became activated while others were not.
B) the drug alone caused ions to flow through the NMDA receptor channel.
C) reduced ion flow through the NMDA receptor channel occurred when glutamate was bound to the receptor with the drug present.
D) greater ion flow through the NMDA receptor occurred when glutamate was bound to the receptor with the drug present.

A) Binding affinity
B) Receptor efficacy
C) Agonism
D) Antagonism

A) Environmental neurotoxicology
B) Toxicology
C) Neurotoxicology
D) Environmental pharmacology

A) Tolerance
B) Sensitization
C) Dependence
D) Drug disposition

A) partial agonist
B) antagonist
C) positive modulator
D) competitive antagonist

A) allow partial activation of a receptor by an agonist.
B) prevent a neurotransmitter from binding to a receptor.
C) prevent the activation of a receptor.
D) have weak affinities for a receptor.

A) Pharmacokinetic
B) Pharmacodynamic
C) Conditioned
D) Behavioral

A) Conditioned
B) Behavioral
C) Pharmacodynamic
D) Pharmacokinetic

A) a physician increased the dose of a drug because a patient became unaffected by the drug.
B) an individual had to increase the amount of drug taken in order to still feel a drug high.
C) a smoker found herself tapping her finger after smoking several cigarettes.
D) a regular drinker realized that he needed to drink even more alcohol than he used to in order feel a buzz.

A) behavior tolerance.
B) sensitization.
C) a psychological withdrawal symptom.
D) a physical withdrawal symptom.

A) pharmacodynamic
B) conditioned
C) behavioral
D) adaptive

A) transmission toxicity.
B) neuronpathy.
C) myelinopathy.
D) axonopathy.

A) sensitization.
B) tolerance.
C) conditioning.
D) dependence.

A) Conditioned
B) Behavioral
C) Cross
D) Drug dispositional

A) dispositional tolerance.
B) a withdrawal syndrome.
C) conditioned tolerance.
D) dependence.

A) behavioral tolerance.
B) conditioned tolerance.
C) cross tolerance.
D) pharmacodynamic tolerance.

A) pharmacokinetic tolerance.
B) pharmacodynamic tolerance.
C) sensitization.
D) conditioned tolerance.

A) Pharmacokinetic
B) Behavioral
C) Conditioned
D) Pharmacodynamic

A) Pharmacokinetic
B) Physical
C) Behavioral
D) Conditioned

A) behavior tolerance.
B) sensitization.
C) a psychological withdrawal symptom.
D) a physical withdrawal symptom.

A) Protein kinases
B) Negative modulators
C) Antagonists
D) Neurotoxins