* - topics that were shown on the 2025 exam
Lecture 1:
Definitions:
Pharmacology: knowledge about drugs or medicines; the art of preparing medication
1. The science that deals with studying the reciprocal actions, or interactions,
between pharmacological substances and physiological processes
Pharmacon: medicine/pharmaceutical product
Drug: pharmacologically active substance (English)
2. Medication or other substance with a physiological effect
3. Psychoactive substance for abuse, narcotic or stimulating
4. Dutch: psychoactive substance for abuse (negative connotation)
Drug/stimulant with a more or less ‘drugging’ effect, which can lead to
dependence (addiction)
Classification
Possible grounds include:
1. Chemical structure
Interesting, but the same structure can have different effects
2. Working mechanism
Ideal, but working mechanism not always known
3. Behavioral effects
Easiest and most used, linked to the disorder being treated
Recently: Behavioral (ATC) -> working (NbN)
1. ATC
The classic system groups drugs based on their purpose (e.g., what they treat), and
their chemical effects.
Anatomical Therapeutic Chemical
Behavioral effects
Indication based
Older (1976)
Gold standard (WHO)
Cons
Use for other than primary disorder
Stigma (i.e., anxiety patient gets prescribed depression drug,
doesn’t want to) -> less patient adherence
2. NbN
A newer system that groups drugs based on how they work in the brain, not just
what they treat.
1
, Neuroscience-based Nomenclature
Working mechanism
Pharmacologically driven
Newer (2018)
Taskforce 5 organizations
The names are based on the primary disorder for which it is prescribed
Cons
New, not acknowledged by WHO/scientific community
Lack of sufficient evidence
Difference in nomenclature ATC vs NbN
1. ATC: anti-psychotics
2. NbN: serotonin/dopamine antagonists with antipsychotic actions
3. ATC: anti-depressants
4. NbN: monoamine reuptake inhibitors with antidepressant action
Classes ATC
1. Psychotropic drug main classes:
Antipsychotics
Conventional (meaning earlier discovered) antipsychotic, e.g.,
Haloperidol
Atypical, e.g., Risperidone
Antidepressants
Tricyclic, e.g., Imipramine
Selective serotonin reuptake inhibitors (SRRI), e.g., Prozac
Monoamine Oxidase Inhibitors (MAOI), e.g., Nardil
Anxiolytics (anti-anxiety medication)
Benzodiazepines, e.g., Valium
Non-benzodiazepines, e.g., Buspirone
Mood stabilizers
Lithium
Hypnotics
2. Other relevant drug classes
Anti-epileptics
Benzodiazepines, Clonazepam, Clorazepate
Stimulants
Cocaine, Amphetamine (speed), Methylphenidate, Ritalin,
Caffeine, Nicotine
Narcotic painkillers
Opioids, Morphine, Codeine, Heroin
Central nervous system (CNS) suppressors (alcohol)
2
, Psychedelics & hallucinogens
LSD, Marijuana, Hashish, Mescaline, Psilocybin (mushroom)
Mescaline -> LSD
o Peyote & San Pedro cactus, really gross (first two hours
of sickness and diarrhea, then 8-10 hours peak)
Administration
Includes 4 important stages
1. Absorption: from the site of administration -> blood
Oral: easy, but stomach acid eats away 2/3 of meds, better safe way if
you expect side effects
Rectal: lose 1/3 of activity
Topical
Skin, e.g., nicotine patches
Oral mucosa
o Sublingual: medicine under your tongue
o Buccal: side between teeth and cheek
Parenteral (injection) works very quickly
Intravenous (in the veins, quick effect because there is no first-
pass metabolism, but difficult to reverse action in case of
allergic reaction)
Intramuscular (in muscle)
Subcutaneously (under the skin, slower)
Inhalation
2. Distribution: throughout the body
In blood (albumin)
Distribution
Extracellular (blood plasma)
Intracellular (water in body cells) important for the medication
to work, easier goes through the membrane, faster and more
effective
Speed depends on lipid solubility
Through membranes: passive diffusion following
concentration gradient
Higher lipid solubility faster distribution
3. Metabolism: conversion by body effect
4. Excretion: elimination from body
Pharmacokinetics: process
3
, Change over time in terms of serum concentration of medication and metabolites. How
does the body process the medication? what happens to a drug in the body after it’s taken
Distribution half-live
Alpha phase: to -> 50%
First half-life = important -> onset action
How fast is it absorbed?
Affects: (ADIME)
Absorption (gets into the bloodstream) except for intravenous
Distribution (gets into tissue from the bloodstream)
Interaction with receptor
Metabolism
Elimination
Blood circulation: most important in pharmacokinetics
Entire blood circulation takes +/- 1 minute
Capillaries
10 billion
200 m2
Every cell gets reached
Pharmacodynamics:
How does the body respond to medication?
Graph: toxic range, therapeutic range, subtherapeutic range
Half-lives: time for the medication to halve in concentration
Distribution half-live
Alpha phase
To -> 50%
Elimination half-live *
Beta phase: degradation (liver) and 50% excretion (kidneys)
Time it takes to eliminate half of the concentration
Sixth half-live = important -> stop action/eliminated
Neurons
4
Lecture 1:
Definitions:
Pharmacology: knowledge about drugs or medicines; the art of preparing medication
1. The science that deals with studying the reciprocal actions, or interactions,
between pharmacological substances and physiological processes
Pharmacon: medicine/pharmaceutical product
Drug: pharmacologically active substance (English)
2. Medication or other substance with a physiological effect
3. Psychoactive substance for abuse, narcotic or stimulating
4. Dutch: psychoactive substance for abuse (negative connotation)
Drug/stimulant with a more or less ‘drugging’ effect, which can lead to
dependence (addiction)
Classification
Possible grounds include:
1. Chemical structure
Interesting, but the same structure can have different effects
2. Working mechanism
Ideal, but working mechanism not always known
3. Behavioral effects
Easiest and most used, linked to the disorder being treated
Recently: Behavioral (ATC) -> working (NbN)
1. ATC
The classic system groups drugs based on their purpose (e.g., what they treat), and
their chemical effects.
Anatomical Therapeutic Chemical
Behavioral effects
Indication based
Older (1976)
Gold standard (WHO)
Cons
Use for other than primary disorder
Stigma (i.e., anxiety patient gets prescribed depression drug,
doesn’t want to) -> less patient adherence
2. NbN
A newer system that groups drugs based on how they work in the brain, not just
what they treat.
1
, Neuroscience-based Nomenclature
Working mechanism
Pharmacologically driven
Newer (2018)
Taskforce 5 organizations
The names are based on the primary disorder for which it is prescribed
Cons
New, not acknowledged by WHO/scientific community
Lack of sufficient evidence
Difference in nomenclature ATC vs NbN
1. ATC: anti-psychotics
2. NbN: serotonin/dopamine antagonists with antipsychotic actions
3. ATC: anti-depressants
4. NbN: monoamine reuptake inhibitors with antidepressant action
Classes ATC
1. Psychotropic drug main classes:
Antipsychotics
Conventional (meaning earlier discovered) antipsychotic, e.g.,
Haloperidol
Atypical, e.g., Risperidone
Antidepressants
Tricyclic, e.g., Imipramine
Selective serotonin reuptake inhibitors (SRRI), e.g., Prozac
Monoamine Oxidase Inhibitors (MAOI), e.g., Nardil
Anxiolytics (anti-anxiety medication)
Benzodiazepines, e.g., Valium
Non-benzodiazepines, e.g., Buspirone
Mood stabilizers
Lithium
Hypnotics
2. Other relevant drug classes
Anti-epileptics
Benzodiazepines, Clonazepam, Clorazepate
Stimulants
Cocaine, Amphetamine (speed), Methylphenidate, Ritalin,
Caffeine, Nicotine
Narcotic painkillers
Opioids, Morphine, Codeine, Heroin
Central nervous system (CNS) suppressors (alcohol)
2
, Psychedelics & hallucinogens
LSD, Marijuana, Hashish, Mescaline, Psilocybin (mushroom)
Mescaline -> LSD
o Peyote & San Pedro cactus, really gross (first two hours
of sickness and diarrhea, then 8-10 hours peak)
Administration
Includes 4 important stages
1. Absorption: from the site of administration -> blood
Oral: easy, but stomach acid eats away 2/3 of meds, better safe way if
you expect side effects
Rectal: lose 1/3 of activity
Topical
Skin, e.g., nicotine patches
Oral mucosa
o Sublingual: medicine under your tongue
o Buccal: side between teeth and cheek
Parenteral (injection) works very quickly
Intravenous (in the veins, quick effect because there is no first-
pass metabolism, but difficult to reverse action in case of
allergic reaction)
Intramuscular (in muscle)
Subcutaneously (under the skin, slower)
Inhalation
2. Distribution: throughout the body
In blood (albumin)
Distribution
Extracellular (blood plasma)
Intracellular (water in body cells) important for the medication
to work, easier goes through the membrane, faster and more
effective
Speed depends on lipid solubility
Through membranes: passive diffusion following
concentration gradient
Higher lipid solubility faster distribution
3. Metabolism: conversion by body effect
4. Excretion: elimination from body
Pharmacokinetics: process
3
, Change over time in terms of serum concentration of medication and metabolites. How
does the body process the medication? what happens to a drug in the body after it’s taken
Distribution half-live
Alpha phase: to -> 50%
First half-life = important -> onset action
How fast is it absorbed?
Affects: (ADIME)
Absorption (gets into the bloodstream) except for intravenous
Distribution (gets into tissue from the bloodstream)
Interaction with receptor
Metabolism
Elimination
Blood circulation: most important in pharmacokinetics
Entire blood circulation takes +/- 1 minute
Capillaries
10 billion
200 m2
Every cell gets reached
Pharmacodynamics:
How does the body respond to medication?
Graph: toxic range, therapeutic range, subtherapeutic range
Half-lives: time for the medication to halve in concentration
Distribution half-live
Alpha phase
To -> 50%
Elimination half-live *
Beta phase: degradation (liver) and 50% excretion (kidneys)
Time it takes to eliminate half of the concentration
Sixth half-live = important -> stop action/eliminated
Neurons
4
