1. Sedative-Hypnotics & the Treatment of Hypersomnia
Mark Beenhakker
Pharmacology

2. b e e n h a k k e r l a b . o r g

3. Sedative-Hypnotics & the Treatment of Hypersomnia
100 ms
20 pA

4. Sedative-Hypnotics & the Treatment of Hypersomnia
+ benzodiazepine
100 ms
20 pA
sedation-hypnosis
anticonvulsant
anxiolysis

5. Sedative-Hypnotics & the
Treatment of Hypersomnia LO
+ benzodiazepine
100 ms
20 pA
sedation-hypnosis
anticonvulsant
anxiolysis

6. Inhibition in the Brain
cell body
synapse
GABA
receptor
axon
Inhibitory Current
100 ms
20 pA
GABA 1

7. Inhibition in the Brain
cell body
synapse
GABA
receptor
axon
Inhibitory Current
+ benzodiazepine
GABA
20 pA
100 ms
Today
GABA Receptors
Benzodiazepines
Barbiturates
Amphetamines 1

8. Two Types of GABA Receptors
ionotropic
metabotropic
outside of neuron
inside of neuron
GABAA
GABAB 2

9. Two Types of GABA Receptors
ionotropic
metabotropic
outside of neuron
binding site
inside of neuron
GABAA
GABAB 2

10. Two Types of GABA Receptors
chloride
GABA
outside of neuron
binding site
inside of neuron
chloride
GABAA
GABAB
Inhibitory Current
20 pA
100 ms 2

11. Two Types of GABA Receptors
potassium/calcium
outside of neuron
binding site
inside of neuron
2nd m.
chloride
GABAA
GABAB
Inhibitory Current
epilepsy
addiction
anxiety & depression
20 pA
100 ms 2 3

12. Two Types of GABA Receptors
potassium/calcium
outside of neuron
binding site
inside of neuron
2nd m.
chloride
GABAA
GABAB
Inhibitory Current
+ benzodiazepine
epilepsy
addiction
anxiety & depression
20 pA
100 ms 2 3

13. GABAA Receptor
outside of neuron
inside of neuron

14. GABAA Receptor
(from above)
5 subunits
chloride pore
(i.e. pentameric)

15. GABAA Receptor (from above) a b g d subunits 5 subunits
chloride pore
(i.e. pentameric) a b g d
subunits

16. GABAA Receptor (from above) g a b b a a b g d subunits 5 subunits
chloride pore
(i.e. pentameric) g a b b a a b g d
subunits

17. GABAA Receptor (from above) g a b b a a b g d subunits 5 subunits
chloride pore
(i.e. pentameric) g
GABA
binding
site a b
GABA b a a b g d
subunits
20 pA
100 ms
Inhibitory Current

18. GABAA Receptor (from above) g a b b a a b g d subunits 5 subunits4
5 subunits
chloride pore
(i.e. pentameric)
BDZ g
GABA
binding
site
benzo
binding
site a b
GABA b a a b g d
subunits
20 pA
100 ms
Inhibitory Current
Inhibitory Current
+ benzodiazepine
20 pA
100 ms

19. Allosteric Modulation5
Allosteric Modulation
definition:
modulation achieved by binding of a drug to a site distinct
from the site required for activation.
- Rudolph & Knoflach, 2011 a b g
GABA
BDZ 7
types:
positive (agonism)
GABA
Relative GABA-
induced current
2.0
0.5
1.0
benzodiazapines
negative (inverse agonism)
bCCE 6
antagonist (blocker)
- Rudolph & Knoflach, 2011
Flumazenil

20. Allosteric Modulation5
Allosteric Modulation
definition:
modulation achieved by binding of a drug to a site distinct
from the site required for activation.
- Rudolph & Knoflach, 2011 a b g
GABA
BDZ 7
types:
positive (agonism)
GABA
+ pos mod
GABA
Relative GABA-
induced current
benzodiazapines
0.5
negative (inverse agonism)
1.0
bCCE 6
2.0
antagonist (blocker)
- Rudolph & Knoflach, 2011
Flumazenil

21. Allosteric Modulation5
Allosteric Modulation
definition:
modulation achieved by binding of a drug to a site distinct
from the site required for activation.
- Rudolph & Knoflach, 2011 a b g
GABA
BDZ 7
types:
positive (agonism)
GABA
+ pos mod
GABA
+ neg mod
GABA
Relative GABA-
induced current
benzodiazapines
0.5
negative (inverse agonism)
1.0
bCCE 6
2.0
antagonist (blocker)
- Rudolph & Knoflach, 2011
Flumazenil

22. Allosteric Modulation5
Allosteric Modulation
definition:
modulation achieved by binding of a drug to a site distinct
from the site required for activation.
- Rudolph & Knoflach, 2011 a b g
GABA
BDZ 7
types:
positive (agonism)
GABA
+ pos mod
GABA
+ neg mod
GABA
+ antag
GABA
Relative GABA-
induced current
benzodiazapines
0.5
negative (inverse agonism)
1.0
bCCE 6
2.0
antagonist (blocker)
- Rudolph & Knoflach, 2011
Flumazenil

23. they lower the lethal dose of other CNS depressants
Benzodiazepines
there are many
Diazepam (Valium) among the first (launched 1963).
4 benzodiazepines are among the 200 most commonly
prescribed drugs in the U.S.
Alprazolam (Xanax)
Clonazepam (Klonopin)
Diazepam (Valium)
Lorazepam (Ativan) a b g
GABA binding site
BAR
actions are dose-dependent:
most sedative hypnotics
(e.g. barbiturates)
anxiolysis
sedation
hypnosis
CNS effects
death
anesthesia 8
Benzodiazepines
benzos by themselves do not:
cause fatalities
produce anesthesia
BUT
they lower the lethal dose
of other CNS depressants
(e.g. alcohol)
dose 9
from Patrice Guyenet, UVA Pharm Dept.

24. they lower the lethal dose of other CNS depressants
Benzodiazepines
there are many
Diazepam (Valium) among the first (launched 1963).
4 benzodiazepines are among the 200 most commonly
prescribed drugs in the U.S.
Alprazolam (Xanax)
Clonazepam (Klonopin)
Diazepam (Valium)
Lorazepam (Ativan) a b g
GABA binding site
BAR
actions are dose-dependent:
anxiolysis
sedation
hypnosis
CNS effects
most sedative hypnotics
(e.g. barbiturates)
death
anesthesia 8
benzos by themselves do not:
cause fatalities
produce anesthesia
Benzodiazepines
+ alcohol
BUT
they lower the lethal dose
of other CNS depressants
(e.g. alcohol)
dose 9
from Patrice Guyenet, UVA Pharm Dept.

25. Benzodiazepines there are many
Diazepam (Valium) among the first (launched 1963).
4 benzodiazepines are among the 200 most commonly
prescribed drugs in the U.S.
Alprazolam (Xanax)
Clonazepam (Klonopin)
Diazepam (Valium)
Lorazepam (Ativan)
actions are dose-dependent:
anxiolysis
sedation
hypnosis
CNS effects
anesthesia
death
Problems
pharmacokinetics
redistribution
metabolism
side effects
flurazepam
ideal hypnotic
Benzodiazepines
ideal anxiolytic 8 16 24
time (hours)
dose
from Patrice Guyenet, UVA Pharm Dept.

26. Benzodiazepine Metabolism
metabolized by the liver (CYPs)
pharmacokinetics highly variable 25 50 75
100
alprazolam
chlordiazepoxide
clonazepam
clorazepate
diazepam
estazolam
flurazepam
lorazepam
midazolam
oxazepam
quazepam
temazepam
triazolam
T1/2 (hours)
Goodman & Gilman, 2011 10

27. Benzodiazepine Metabolism
metabolized by the liver (CYPs)
pharmacokinetics highly variable 25 50 75
100
T1/2 (hours)
Goodman & Gilman, 2011
short-acting (t1/2<6hrs) 10
intermediate-
acting (t1/2: 6-24hrs)
long-acting (t1/2>24hrs)
alprazolam
clonazepam
clorazepate
diazepam
estazolam
flurazepam
lorazepam
midazolam
oxazepam
quazepam
temazepam
triazolam
chlordiazepoxide
age-dependent 40 80 25 50 75
100
Age (years)
T1/2 (hours)
from Patrice Guyenet, UVA Pharm Dept. 11
over-sedation can occur with ‘standard doses’
can be sex-dependent
Greenblatt et al., 2000

28. Benzodiazepines: Effect Selectivity
anesthesia
death
anxiolysis
sedation
hypnosis
CNS effects 8 16 24
time (hours)
Benzodiazepines
ideal hypnotic
ideal anxiolytic 12
CNS effects

29. GABAA Receptor (from above) g a b b a a b g d subunits 5 subunits
chloride pore
(i.e. pentameric) g
GABA
binding
site
benzo
binding
site a b b a a b g d
subunits
Inhibitory Current
+ benzodiazapene
20 pA
100 ms

30. GABAA Receptor (from above) g a b b a a1-6 b1-3 g1-3 d subunits
chloride pore
(i.e. pentameric) g
GABA
binding
site
benzo
binding
site a b b a
a1-6
b1-3
g1-3 d
subunits
Inhibitory Current
+ benzodiazapene
20 pA
100 ms

31. GABAA Receptor (from above) g a b b a a1-6 b1-3 g1-3 d subunits a1 a2
chloride pore
(i.e. pentameric) g
GABA
binding
site
benzo
binding
site a b b a
a1-6
b1-3
g1-3 d
subunits a1 a2 a3 a5
other
Inhibitory Current
+ benzodiazapene
20 pA
100 ms

32. a Subunits and Selectivity
Sedation
Anxiolysis
Muscle
Relaxation
Anti-
Convulsant
the good
Amnesia
Addiction
the bad
Tan et al., 2011

33. a Subunits and Selectivity
the good
Amnesia
Addiction
the bad
Muscle
Anti-
Sedation Anxiolysis
Relaxation
Convulsant
Tan et al., 2011

34. a Subunits and Selectivity
a2-selective agents
a1-selective agents
20-fold higher affinity for
receptors containing a1
subunits a1 a2
non-sedating anxiolytics
hopefully soon…
‘Z compounds’
technically non-benzos
good for insonmia a3 a5
benzodiazepine Cl
CH3 O
diazepam
O2N H
clonazepam
imidazopyridine 14 13
(zolpidem)
Rudolph & Knoflach, 2011

35. Benzodiazepines: Therapeutic Uses15
Benzodiazepines: Therapeutic Uses
maximize therapy, minimize side-effects
sedation-hypnosis
true benzodiazepines
Triazolam (closest to ‘ideal hypnotic’)
anesthesia
death
anxiolysis
sedation
hypnosis 8 16 24
time (hours)
ideal hypnotic
Flurazepam (less ‘early morning insomnia’)
Z compounds
Zolpidem (Ambien)
Zaleplon (Sonata)
Eszopiclone (Lunesta) 16

36. Benzodiazepines: Therapeutic Uses15
Benzodiazepines: Therapeutic Uses
maximize therapy, minimize side-effects
sedation-hypnosis
true benzodiazepines
Triazolam (closest to ‘ideal hypnotic’)
anesthesia
death
anxiolysis
sedation
hypnosis 8 16 24
time (hours)
ideal hypnotic
Flurazepam (less ‘early morning insomnia’)
Z compounds
Zolpidem (Ambien)
ideal anxiolytic
Zaleplon (Sonata)
Eszopiclone (Lunesta) 16
anxiolysis
most benzos with medium- to long-T1/2 work
low doses often used
a2-selective benzos are actively being developed
severe anxiety:
associated with prominent autonomic signs (e.g. panic disorders)
high-potency benzos used
Lorazepam (Ativin)
Alprazolam (Xanax)
Clonazepam (Klonopin)
anticonvulsant
only a few used (e.g. lorazepam, clonazepam, clorozepate)

37. Benzodiazepines: Last Couple of Things
Tolerance
primarily observed with anticonvulsant actions 17
limited tolerance observed with sedative-hypnotic &
anxiolytic effects
Dependence/Addiction
physical dependence is usually mild
follows general rule of drug dependence:
higher dosage = more severe withdrawal
longer t1/2 = less severe withdrawal
estimated that % of adult population abuse or are
dependent upon benzos (300, ,000 people in the U.S.)
GABA receptors live in the VTA (ventral tegmental area)
modulating GABA receptor activity in the VTA hypothesized
to increase dopamine release
Benzodiazepine blocker
Flumazenil (Romazicon) 18
benzodiazepine stupor
potential risk of seizures

38. Sedative-Hypnotics & the
Treatment of Hypersomnia

39. Barbiturates Directly bind to GABA binding site (at high doses)
activates channel and causes chloride conductance a b g
GABA binding site
BAR 19
High doses are fatal
anesthesia
death
anxiolysis
sedation
hypnosis
CNS effects
dose
Benzodiazepines
most sedative hypnotics
(e.g. barbituates)
alcohol 20
Once extensively used as sedative-hypnotics. Now largely
replaced by the much safer benzos.
noteworthy exceptions:
Pentobarbital (insomnia, pre-op sedation, seizures)
Phenobarbital (seizures)
Thiopental (induction/maintenance of anesthesia)….short-lasting

40. Amphetamine Ma huang ‘looking for trouble’
Resembles catecholamines but more lipid soluble (can cross BBB)
catecholamines: norepinephrine, dopamine, serotonin
indirectly-acting sympathomimetic amine
norepinephrine
amphetamine
NH2
amphetamine and related drugs stimulate release of:
dopamine stimulates reward mechanisms, causes psychosis/addiction
CNS
norepinephrine increased vigilance, anorexia
serotonin increased vigilance, anorexia
norepinephrine hypertension, strokes, arrhythmias
sympathetic
nerve
terminals 21

41. Amphetamine: Mechanism
cell body
synapse
GABA
receptor
axon
GABA

42. Amphetamine: Mechanism
cell body
synapse
axon 22
norepinephrine

43. Amphetamine: Mechanism22
axon terminal

44. Amphetamine: Mechanism22
axon terminal

45. Amphetamine: Mechanism22
norepinephrine
NET (NE Transporter)
axon terminal
vesicle
transporter 2)
VMAT2 (vesicular monoamine
Catecholamine uptake via
plasmalemmal transporter
Packaged in vesicles for
subsequent release

46. Amphetamine: Mechanism22
norepinephrine
amphetamine
amphetamine is a
weak lipophilic base
(pKa = 9.9)
NET (NE Transporter)
reverse transport
axon terminal
vesicle
Catecholamine uptake via
plasmalemmal transporter
plus amphetamine
Reverse transport leads to
catecholamine release
Packaged in vesicles for
subsequent release
Alkalinization shuts down vesicular
catecholamine sequestration

47. Amphetamine d-isomer 3-4 times more potent than l-isomer
Powerful CNS stimulant
d-isomer 3-4 times more potent than l-isomer
d-amphetamine: Dextroamphetamine (Dexedrine, Dextrostat)
Lisdexamfetamine (Vyvanse): inactive, prodrug of d-amphetamine
Clinical uses:
Hypersomnia (Excessive Daytime Sleepiness [EDS])
narcolepsy ( % of the US population)
obstructive sleep apnea
shift-worker disorder (EDS affects >30% of night-shift workers)
Attention Deficit Hyperactivity Disorder 23
Adverse/toxic effects
Usually result from overdosage
Acute toxic effects usually an extension of therapeutic effects.
restlessness, dizziness, tenseness, insomnia
Cardiovascular/GI side effects
Alternatives
Modafinil (Provigil): promotes wakefulness, reduces EDS in narcoleptics
mechanism(s) not well-understood (but activates wake-promoting neurons) 24
little/no cardiovascular/cognitive side effects (main side effect = headaches)
may be used to reduce cocaine dependence

48. Sedative-Hypnotics & the Treatment of Hypersomnia
Inhibition in the Brain

49. Sedative-Hypnotics & the Treatment of Hypersomnia
Inhibition in the Brain
Benzodiazepines: positive
allosteric modulators of GABAA R’s a b g
GABA
BDZ
20 pA
100 ms
Benzodiazepines: dose-
dependent effects
Benzodiazepines: T1/2’s highly
variable
Benzodiazepines: ideal
hypnotic VS anxiolytic
Benzodiazepines: a subunits

50. Sedative-Hypnotics & the Treatment of Hypersomnia
Inhibition in the Brain
Barbiturates: directly
activate GABAA R’s a b g
BDZ
20 pA
100 ms
BAR
Benzodiazepines: positive
allosteric modulators of GABAA R’s a b g
GABA
BDZ
20 pA
100 ms
Benzodiazepines: dose-
dependent effects
Benzodiazepines: T1/2’s highly
variable
Benzodiazepines: ideal
hypnotic VS anxiolytic
Benzodiazepines: a subunits

51. Sedative-Hypnotics & the Treatment of Hypersomnia
Inhibition in the Brain
Barbituates: directly
activate GABAA R’s a b g
BDZ
20 pA
100 ms
BAR
Benzodiazepines: dose-
dependent effects
Benzodiazepines: T1/2’s highly
variable
Benzodiazepines: ideal
hypnotic VS anxiolytic
Benzodiazepines: a subunits

52. Sedative-Hypnotics & the Treatment of Hypersomnia
Inhibition in the Brain
Barbituates: directly
activate GABAA R’s a b g
BDZ
20 pA
100 ms
BAR
100 ms
20 pA
Benzodiazepines: dose-
dependent effects
Benzodiazepines: T1/2’s highly
variable
Amphetamine: catecholamine
release
Benzodiazepines: ideal
hypnotic VS anxiolytic
Benzodiazepines: a subunits
suggested reading
Basic & Clinical Pharmacology, 12th ed. (chapter 22)
Bertram G. Katzung, Susan B. Masters, Anthony J. Trevor
Pharmacological Basis of Therapeutics, 12th ed. (Chapter 17)
Goodman & Gilman
questions: