Lectures 17_Physicochemical properties of Drug molecules-2_Henderson HasselBach Equation; Chiral Drugs PDF

Summary

These lecture notes cover physicochemical properties of drugs, including functional group effects, acidity/basicity, chirality and solubility. Concepts from the Henderson-Hasselbalch equation and chiral drug properties are also discussed. The document discusses the calculation of percent ionization of drugs at various pH values and different scenarios related to chiral drugs.

Full Transcript

Medicinal Chemistry

Drug

Physicochemical Properties of
Drugs - 1

Functional Group (FG)
1. Electronic Effects, 2.
Steric Effects, 3. Acidity
and Basicity of FG

Physicochemical Properties of Drugs- 2, 3

4. Chirality
5. Salt and Solubility
 Physicochemical properties of Drug molecules -1

Chemical Properties of Functional
FG

Groups
FG is a part of a compound/drug which provides specific
properties and behaviors that allow a compound/drug to
produce biological response.
Chemical Properties of FGs:
(1) Electronic Effects: Resonance and Inductive Effect
(2) Steric Effects
(3) Acid-base Properties
(4) Chirality
(5) Solubility Effects: Water and Lipid Solubility, Salt
Formation

Lecture # 17
 Henderson-Hasselbach FG
3. Acid-Base properties
Equation
First described by Lawrence Henderson in 1908 and later revised by Karl

Weak Acids
Hasselbach in 1916.

HA H + A
Acid Conjugate Base [ionized]

[un-ionized]

[acid]
or pKa = pH + log
[conjugate base]
 Weak Bases
B:H H + B:
Conjugated Acid Base
(Protonated (Unprotonated
Form) Form)

[base]
pH = pKa + log
[conjugate acid]

[un-ionized]
or pH = pKa + log
[ionized]
 FG
Addition properties

Calculation of percent ionization of amobarbital at pH 2.0, pH 8.0,
and pH 7.4.

Foye's Principles of Medicinal Chemistry
At a pH of 8.0 there are equal amounts of acid form
and conjugate base (or ionized) form:

-
[A ]
8 = 8 + log
[HA]
-
[A ]
0 = log
[HA]
-
0 1 [A ]
10 = =
1 [HA]
[A-] + [HA] = 1 + 1 = 2

- [A-]
% [A ] = - X 100
[A ] + [HA]
1
-
% [A ] = X 100 = 50%
2
 FG
Addition properties

pH = 7.4
-
[A ]
7.4 = 8.0 + log
[HA]
-
[A ]
-0.6 = log
[HA]
0.25 [A-]
=
1 [HA]
[A-] + [HA] = 1 + 0.25 = 1.25

- [A-]
% [A ] = X 100
[A-] + [HA]

0.25 X 100 = 20%
% [A-] =
1.25
The calculation indicates that 20% of the molecules are in the conjugate base (or
ionized) form, leaving 80% in the acid (unionized) form.
Foye's Principles of Medicinal Chemistry
 At a pH of 5.5, the acid form
predominates (99.7%).

At pH 2.0 amobarbital is in the acid or
unionized form (100%) since the pH is 6
log units below the pKa of the compound.
 FG
3. Acid-Base properties

Calculation of percent ionization of phenylpropanolamine at pH of 2.0 and pH of
5.5.

Foye's Principles of Medicinal Chemistry
 2.0 = 9.4 + Log [un-ionized]/[ionized]
Unionized is the base form and ionized is the conjugate acid.

2.4 – 9.4 = Log [un-ionized]/[ionized]

-7 = Log [un-ionized]/[ionized] or 7 = Log [ionized]/[un-ionized]

[un-ionized]/[ionized] = 10-7/1 or [ionized]/[un-ionized] = 107

Percentage of ionization = 107/(1 + 107) X 100 = 99.99%

At a pH of 2.0 the compound exists in the conjugate acid (ionized) form (>99%) as
shown. At a pH of 5.5 phenylpropanolamine is 99.7% ionized, and at pH 8.0 the
conjugate acid form still predominates, but it has decreased to 96%.
 Pharmacist Trapping of Morphine in
Alert
Stomach
The drug is slightly more
than 50% nonionized in
the plasma (pH
approximately 7.4)
because it is in an
environment with a pH
that is slightly less than
pKa.

In the stomach (pH
approximately 2), the
drug is highly ionized, it
cannot diffuse across
the cells lining the
stomach, and the drug
molecules
are trapped in the
stomach.
https://clinicalgate.com/pharmacokinetics/
Pharmacist Alkalinization of Urine
Alert to Eliminate Drugs
Alkalinization of
the urine is used
to increase the
excretion of
acetylsalicylic acid
(aspirin), an acidic
drug.

Increasing the pH
of urine above the
pKa of
acetylsalicylic acid
increases the
proportion of the
drug in the ionized
state by about
10,000 times.
https://clinicalgate.com/pharmacokinetics/
Pharmacist
Alert Urine Alkalinization
Urine alkalinization is a treatment regimen
that increases poison elimination by the
administration of intravenous sodium
bicarbonate or oral tablets to produce
urine with a pH > 7.5 or more.
Urine alkalinization increases the urine
elimination of mecoprop (herbicide),
methotrexate, phenobarbital, and salicylate.

Mecoprop Methotrexate Phenobarbital
Pharmacist AlertAcid, Base, and Absorption
Ecstasy gets into the brain easily.
Ecstasy is a weak base. Once the
Ecstasy has accepted a H+, it has a
charged character, which makes it
difficult to cross a biological membrane.
Therefore, most of the Ecstasy is not
absorbed from the stomach into the
bloodstream.

In the small intestine the more alkaline
environment causes Ecstasy to give up
its H+, becoming nonpolar, enabling the
Ecstasy molecules to diffuse across the
membrane into the blood capillaries.

Eventually Ecstasy crosses the blood
brain barrier into the brain very easily.

It will take about 15 min. for Ecstasy to
reach the brain if taken on empty http://www.nida.nih.gov/teaching4/teaching2.html
stomach.
 Rule of thumb

Weak acids— HA ↔ A- (—COOH ↔ —COO–)
– When pH is below the pKa, acids are more likely to be in the
un-ionized (HA) form. The un-ionized form can diffuse through
lipid membrane.

Weak bases— BH+ ↔ B (—NH3+ ↔ —NH2)
– When pH is below the pKa, bases are more likely to be in the
ionized (BH+) form. The ionized form will not diffuse through
lipid.

In the stomach (at pH 2), most acids will diffuse
through membrane (absorb), but bases will not.

In the small intestine (at pH 4.8-8.2), most acids will
not absorb, but most bases will.
 Key Facts to Remember!

How to use the Henderson-Hasselbach Equation for
calculating the percentage of ionization

Calculate % ionization in the given drug at the provided
pH.

For acidic drugs when pH > pKa, mostly ionized.
For acidic drugs when pH  pKa, mostly unionized.
For basic drugs when pH > pKa, mostly unionized.
For basic drugs when pH  pKa, mostly ionized.
 Physicochemical properties of Drug molecules -1

Chemical Properties of Functional
FG

Groups
FG is a part of a compound/drug which provides specific
properties and behaviors that allow a compound/drug to
produce biological response.
Chemical Properties of FGs:
(1) Electronic Effects: Resonance and Inductive Effect
(2) Steric Effects
(3) Acid-base Properties
(4) Chirality
(5) Solubility Effects: Water and Lipid Solubility, Salt
Formation
 3. Chirality
Stereochemistry
(The orientation of functional groups in three-dimensional space is
referred to as the molecules’ stereochemistry.)
Asymmetric Carbon (chiral carbon): A carbon
atom attached to four substituents that are
different.

Amoxicillin

A molecule containing “n” asymmetric carbons will
give rise to 2n optical isomers.
The spatial arrangement affects the way it reacts in
chemical reactions and its biological and physical properties
Molecules with the same molecular formula but differing in
the arrangement of their atoms in space are called
stereoisomers.

Stereoisomers may have very different biological properties. For
example, Ibuprofen exists as a racemic mixture, but only the S
enantiomer has analgesic properties.
 Different types of
stereoisomers:
enantiomers,
diastereomers, geometric
Enantiomers: non-superimposable mirror
image isomers

Diastereomers: non-superimposable, non-
mirror image. isomer (more than one
chiral center)

Geometric isomers (diastereomers): E / Z
alkene isomers
 Absolute configuration (Cahn-Ingold-
Prelog rules)
The description of the order of the
ligand atoms in space (Spatial H 1
Arrangement) C 6
N 7
R, S convention is determined by the O 8
atomic numbers of the F 9
P 15
substituents closest to the S 16
stereogenic center. Cl 17
R (rectus, “right”: “clockwise”) Br
I
35
53
S (sinister, “left”: “counter-clockwise”)
The Absolute Configuration (the precise three-dimensional arrangement of
atoms in space) can be assigned by the R/S method as follows:
(1) Assign priorities to the ligands from 1 (highest priority) to 4 (lowest
priority). (A substituent with a higher atomic number takes
precedence over a substituent with a lower atomic number.
Hydrogen is the lowest possible priority substituent because it has
the lowest atomic number.)
(2) Rotate the molecule so that ligand number 4 is in the back. (Dashes
indicate pointing away from the viewer.) (Wedges indicate coming
towards the viewer.)
(3) If the direction for the numbers 1 to 3 is clockwise, assign R (rectus,
Right), if counterclockwise, assign S (sinister, LEFT).

H

N
(R)

H

H2N
(S)
Problems:

Solutions:
1. S: I > Br > F > H. The lowest priority substituent, H, is already going towards the back. It turns left going
from I to Br to F, so it's a S.
2. R: Br > Cl > CH3 > H. You have to switch the H and Br in order to place the H, the lowest priority, in the
back. Then, going from Br to Cl, CH3 is turning to the right, giving you a R.
3. Neither R or S: This molecule is achiral. Only chiral molecules can be named R or S.
4. R: OH > CN > CH2NH2 > H. The H, the lowest priority, has to be switched to the back. Then, going from
OH to CN to CH2NH2, you are turning right, giving you a S.
(5) S: −COOH > −CH2OH > C≡CH > H. The H, the lowest priority, has to be switched to the back.
Then, going from −COOH to −CH2OH to −C≡CH you are turning left, giving you an S configuration
 Stereochemistry and Biologic Activity
Easson-Stedman Hypothesis

They postulated that such interactions require a minimum of a
three-point fit to the receptor (minimum of three
intermolecular interactions)

The less potent enantiomer interacts with less sites.
 Drug receptor interaction of R-(−)-epinephrine, S-(+)-
epinephrine, and N-methyldopamine

Optical isomers. Only in compound 6 do
the functional groups A, B, and C align
with the corresponding sites of binding (A′,
B′, and C′) on the asymmetric surface.
 Optical Rotation []D of plane Polarized light.
(+) = d (dextrorotatory)
(-) = l (levorotatory)

Note that the sign of optical rotation (+) or (-) is
not related to the R, S designation

(+) and (-) refer to the effect of the compound
on the direction of rotation of plane-
polarized light and have nothing to do with the
stereochemical configuration of the molecule.
 Key Points
Enantiomeric: Not Superimposable
Racemate: An equal mixture of two
enantiomers
Amino acids are chiral molecules (All L-
isomers)
Proteins are also chiral.
The interactions between chiral proteins
(receptors) and different enantiomers
of chiral drugs may involve different
binding sites.
Different Scenarios (Interesting
facts)
A. One enantiomer is more potent than
the other
– The S-(+)-isomer of antihistamine
dexchlorpheniramine is 200 times more
potent than the R-(-)-isomer.

B. Both isomers are biologically active,
but only one contributes to the
toxicity
– Fluoxetine
 (±)Fluoxetine (Prozac),
E. Lilly
R and S isomers are
equally potent as
selective serotonin
reuptake inhibitor
(SSRI)
R isomer shows small
but significant cardiac
side effect
S isomer works well
for the anti-migraine
effect, but a racemic
mixture has no effect.

https://www.youtube.com/watch?v=cWx6RbBVTnA
Pharmacist Alert
C. One isomer may contribute to undesirable side
effects and significant toxicity
Currently used for
– thalidomide advanced leprosy and
multiple myeloma, and
various other solid and
hematologic
malignancies.

over 10,000 babies wer
affected by the drug
worldwide. Around half
Birth defect was caused by the (S)-isomer died within months of
(R)-Isomer was converted in to the (S)-isomer in vivoborn.
being
D. Enantiomers may have different
therapeutic activities.
Darvon, 2R, 3S-(+)-dextropropoxyphene, is an
analgesic drug.
Novrad, 2S,3R-(-)-levopropoxyphene, is an
antitussive agent.
E. It, also, is possible for enantiomers to
have opposite effects.
The (+)-isomer of the experimental narcotic
analgesic picenadol is an opiate agonist, the (-)-
isomer is a narcotic antagonist, and the
racemate is a partial agonist.
F. Two enantiomers may have synergistic
pharmacological activities.
The (+)-isomer of the antihypertensive drug
nebivolol (Nebilet) is a -blocker.
The (-)-isomer is not a -blocker, but it is still a
vasodilating agent (via the nitric acid pathway).
The drug is sold as a racemate to take
advantage of two different antihypertensive
 Separation of
enantiomers
In general, about a third of drugs are sold as
racemic mixtures, even though at least half of
the mixture not only may be inactive for
desired biological activity, but may, in fact, be
responsible for various side effects.
It can be quite expensive to separate the
enantiomeric impurity.
The FDA has been satisfied if the racemate
has low toxicity in human studies.
 Chiral drugs and the market
New patent for marketing single enantiomer even
the racemate is covered by an active patent.
AstraZeneca marketed the antiulcer drug
omperazole (prilosec) as racemate.
Shortly before the patent expired, a new patent
was issued to the same company for the active
(S)-isomer which was approved for marketing as
esomeperazol (nexium).
Single isomer drug sales have been steadily
increasing worldwide.
 Key Points

Identify chiral carbon atoms that are present in the
drug molecules.

Be able to analyze drug structure to find the number of
chiral carbons

Analyze absolute configuration in a given drug molecule.

Understand the differential potency and efficacy of
stereoisomeric drug molecules.
 Medicinal Chemistry

Drug

Physicochemical Properties of
Drugs - 1

Functional Group (FG)
1. Electronic Effects, 2.
Steric Effects, 3. Acidity
and Basicity of FG

Physicochemical Properties of Drugs- 2, 3
4. Chirality
5. Salt and Solubility