Prodrug All Lectures (2) PDF

Summary

These are lecture notes on prodrugs and drug delivery systems. The document discusses various aspects of prodrugs, including their types, mechanisms of activation, and applications in medicine.

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The Organic Chemistry of Drug Design
and Drug Action

Prodrugs and Drug Delivery Systems
Dr.yahya saad yaseen
 Prodrugs and Drug Delivery Systems
Drug Discovery:
1. Drug design and development
2. Drug Design: optimizing target interaction
3. Drug Design: Optimizing access to the
target
 Prodrugs and Drug Delivery Systems
Prodrug : a pharmacologically inactive compound that is
converted to an active drug by a metabolic
biotransformation
Ideally, conversion occurs as soon as the desired goal for
designing the prodrug is achieved.
 Utility of Prodrugs
1. Aqueous Solubility : to increase water solubility so it
can be injected in a small volume
2. Absorption and Distribution: to increase lipid
solubility to penetrate membranes for better absorption
3. Site Specificity :the extent to which a drug produces
only the desired therapeutic effect without causing any
other physiological changes. A drug with high specificity
exhibits a strong drug–receptor interaction, ensuring
targeted action and minimal side effects
 Utility of Prodrugs (cont’d)
4. Instability :to prevent rapid metabolism; avoid first-
pass effect
5. Prolonged Release: to attain a slow, steady release of
the drug
6. Toxicity : to make less toxic until it reaches the site of
action
7. Poor Patient Acceptability :to remove an unpleasant
taste or odor; gastric irritation
8. Formulation Problems : to convert a drug that is a gas
or volatile liquid into a solid
Types of Prodrugs
rational prodrug design
 Types of Prodrugs
rational prodrug design
I. Carrier-linked prodrug:
A compound that contains an active drug linked to a carrier group
that is removed enzymatically
A. bipartate : comprised of one carrier attached to drug
B. tripartate : carrier connected to a linker that is connected to drug
#tripartite agreement involves three parties while bipartite
agreement involves two parties
II. Bioprecursor prodrug
A compound metabolized by molecular modification into a new
compound, which is a drug or is metabolized further to a drug - not
just simple cleavage of a group from the prodrug—e.g., amine
getting oxidized to CO2H, to afford the active.
 Mechanisms of Prodrug Activation
Carrier-Linked Prodrugs

Most common activation reaction is hydrolysis.
Rate of hydrolysis can be modified by locating
alkyl groups in area of the carbonyl group to
Increase steric hindrance, and retard hydrolysis
rate.
 Ideal Drug Carriers
1. Protect the drug until it reaches the site of action
2. Localize the drug at the site of action
3. Allow for release of drug
4. Minimize host toxicity
5. Are biodegradable, inert, and nonimmunogenic
6. Are easily prepared and inexpensive
7. Are stable in the dosage form
 Carrier Linkages for Various Functional Groups
Alcohols, Carboxylic Acids, and Related Groups

Most common prodrug form is an ester
esterases are ubiquitous
can prepare esters with any degree of hydrophilicity or
lipophilicity
ester stability can be controlled by appropriate
electronic and steric manipulations
Prodrugs for Alcohol- Drug—OH Drug—OX

Containing Drugs alcohols
X Effect on Water Solubility

O
(R = aliphatic or aromatic)
C—R decreases (increases lipophilicity)

O
+ increases (pKa ~ 8)
C—CH 2NHMe2

O
increases (pKa ~ 5)
C—CH 2CH2COO-

O
increases (pKa ~ 4)
C
Ester analogs as NH
+
prodrugs can affect PO3= (phosphate ester)
increases (pKa ~ 2 and ~ 6)

lipophilicity or O
hydrophilicity CCH 2SO3-
increases (pKa ~ 1)
To accelerate hydrolysis rate:
attach an electron-withdrawing group if a base
hydrolysis mechanism is important
attach an electron-donating group if an acid
hydolysis mechanism is important

To slow down hydrolysis rate:
make sterically-hindered esters
make long-chain fatty acid esters
 Another Approach to Accelerate
Hydrolysis
Intramolecular hydrolysis of succinate esters

O
H OH O
-O
COO-
Drug—O - O Drug—OH + -OOC

Drug—O
O
O

Also, acetals or ketals can be made for rapid
hydrolysis in the acidic medium of the GI tract.
Enolic hydroxyl groups can be esterified as well.
HOOC

S
OH O
F O S
F
O
N O
Cl
Cl N
O
O
H2N
H2N
oxindole
8.1 8.2
antirheumatic agent
Carboxylic Acid-Containing Groups

Esterify as with alcohols
 Maintaining Water Solubility of
Carboxylate Prodrugs

O
+
Drug—C—O—CH2CH2—NRR' 2

8.3

Can vary pKa by appropriate choice of R and R
 Prodrugs for Phosphate- or
Phosphonate-Containing Drugs
O
O O
P
O

2

8.4
 Amine Prodrugs
Drug—NH 2 Drug—NHX

X

O O O O
+
CR CCHNH3 C OPh —CH 2NHCAr CHAr NAr
R

#Amides are commonly not used because of stability
#Activated amides (low basicity amines or amino
acids) are effective
# pKa of amines can be lowered by 3 units by conversion to N-
Mannich bases (X = CH2NHCOAr)
N-Mannich base (R = CH2NHCOPh) has a log D7.4
two units greater than the parent compound.
OH

CH3
NHR

phenylp ropanolamine hydrochlo ride (R = H. HCl)
8.5
Another approach to lower pKa of amines and
make more lipophilic.
Imine (Schiff base) prodrug
OH
O
N
F NH 2
hydrolyze imine and
amide to GABA
anticonvulsant Cl inside brain
proga bide
8.6
 A Reductive Carrier-Linked Prodrug
Approach
OH
OH
N
NO2 :NH
Y Y Y
bioreductio n XH
Drug +
X Z X Z Z
Drug Drug
8.7 8.8
 Prodrugs of Sulfonamides
A water soluble prodrug of the anti-inflammatory
drug valdecoxib (8.9) has been made (8.10).

Ph N Ph N
O O
Na+
H2N CH3 N CH3
S S
O O O O O

valdecoxib parecoxib sodiu m
8.9 8.10
 Prodrug Analogs of
Carbonyl Compounds
Drug Drug X
C=O C
R R Y

X
C
Y

OR' O S
C=NR' C=NOH C C C
OR' N N
H H

imines oximes ketals
Examples of Carrier-Linked
Bipartate Prodrugs
 1. Prodrug for O
Increased Water R' = CCH2CH2CO2 Na
Solubility OH OR'
Me Prodrug forms
HO
O
Me R' = PO3Na 2
for aqueous injection or
opthalmic use
O
R
predniso lone (R = R' = H ) poor water
methylpredniso lone (R = CH3 , R' = H) solubility
8.11
corticosteroid
Choice of water solubilizing group: The ester must be stable enough
in water for a shelf life of > 2 years (13 year half-life), but must be
hydrolyzed in vivo with a half-life < 10 minutes.
Therefore, in vivo/in vitro lability ratio about 106.
To avoid formulation of etoposide with detergent, PEG,
and EtOH (used to increase water solubility), it has been
converted to the phosphate prodrug.

O O
CH 3 O
HO O
HO
O
O
O
O

CH 3O OCH 3
OR

etoposide (R = H)
etoposide phosph ate (R = PO3 H2 )
8.12
2. Prodrug for Improved Absorption
Through Skin
OR
O
CH3 CH3
HO O
CH3
CH3 O

F
O
F
fluocinolone acetonide (R = H)
fluocinon ide (R = COCH3 )
8.14
corticosteroids - inflammation, allergic,
pruritic skin conditions
Better absorption into cornea for the treatment of
glaucoma
RO
OH
RO
NHCH3

dipivefrin (R = Me3 CCO)
epinephr ine (R = H )
8.15

The cornea has significant esterase activity
3.Prodrug for Site Specificity
RO Bowel sterilant
OR

O
N
H
oxyphenisatin (R = H) (administer rectally)
8.16

prodrug R = Ac (administer orally)
hydrolyzed in intestines
 3. Prodrug for Site Specificity
The blood-brain barrier prevents hydrophilic molecules
from entering the brain, unless actively transported. The
anticonvulsant drug vigabatrin.crosses poorly. A glyceryl
lipid (8.17, R = linolenoyl) containing one GABA ester and
one vigabatrin ester was 300 times more potent in vivo than
vigabatrin.

OCOR
O NH2
O
O
NH2
O
8.17
 OR
Site Specificity
Using Enzymes at
the Site of Action

RO
diethylstilbestrol diphosphate (R = PO3= )
diethylstilbestrol (R = H)
8.18
Phosphatase should release the drug selectively in
tumor cells. This approach has not been successful
because the prodrugs are too polar, enzyme selectivity
is not sufficient, or tumor cell perfusion rate is poor.
 Enzyme-Prodrug Therapies

For selective activation of prodrugs in tumor cells
Two steps:
1. incorporate a prodrug-activating enzyme into a
target tumor cell
2. administer a nontoxic prodrug which is a
substrate for the exogenous enzyme incorporated
 Criteria for Success with Enzyme-Prodrug
Therapies

1.The prodrug-activating enzyme is either nonhuman or a
human protein expressed poorly
2.The prodrug-activating enzyme must have high catalytic
activity
3.The prodrug must be a good substrate for the
incorporated enzyme and not for other endogenous
enzymes
4.The prodrug must be able to cross tumor cell membranes
5. The prodrug should have low cytotoxicity and the
drug high cytotoxicity
6. The activated drug should be highly diffusible to kill
neighboring non expressing cells (bystander killing
effect)
7. The half-life of the active drug is long enough for
bystander killing effect but short enough to avoid
leaking out of tumor cells
 Antibody-Directed Enzyme Prodrug Therapy
(ADEPT)
An approach for site-specific delivery of cancer drugs.
Phase One:
An antibody-enzyme conjugate is administered which binds to the
surface of the tumor cells.
The antibody used has been targeted for the particular tumor cell.
The enzyme chosen for the conjugate is one that will be used to cleave
the carrier group off of the prodrug administered in the next phase.
Phase Two:
After the antibody-enzyme has accumulated on the tumor cell and
the excess conjugate is cleared from the blood and normal tissues,
the prodrug is administered.
The enzyme conjugated with the antibody at the tumor cell
surface catalyzes the conversion of the prodrug to the drug
when it reaches the tumor cell.
Advantages:
ADEPT
1. Increased selectivity for targeted cell
2. Each enzyme molecule converts many prodrug
molecules
3. The released drug is at the site of action
4. Demonstrated to be effective at the clinical level
5. Concentrates the drug at the site of action
Disadvantages:
1. Immunogenicity and rejection of antibody-enzyme
conjugate
2. Complexity of the two-phase system and i.v.
administration
3. Potential for leakback of the active drug
An example is carboxypeptidase G2 or alkaline
phosphatase linked to an antibody to activate a nitrogen
mustard prodrug.

I I I I
N N
carboxypeptidase G2
+ L-Glu + CO2

H
O N CO2H OH

O CO2H
electron-do nating;
8.19 activates nitrogen mustard
electron-withdrawing;
deactivates nitrogen mustard

Humanization of antibodies minimizes immunogenicity.
Note the prodrug-activating enzyme is a bacterial enzyme.
Antibody-Directed Abzyme Prodrug Therapy
(ADAPT)
Instead of using a prodrug-activating enzyme,
humanized prodrug-activating catalytic antibody
(abzyme) can be used.
Ideally, the abzyme catalyzes a reaction not known to
occur in humans, so the only site where the prodrug
could be activated is at the tumor cell where the
abzyme is bound.
Antibody 38C2 catalyzes sequential retro-aldol and
retro-Michael reactions not catalyzed by any known
human enzyme.
Found to be long-lived in vivo, to activate prodrugs
selectively, and to kill colon and prostate cancer cells.
 Abzyme 38C2 Activation of a
Doxorubicin Prodrug

O OH O O OH O O OH O
OH OH OH
38C2 38C2
OH OH OH

CH3O O OH H O CH3O O OH H O B- O CH3O O OH H O
O
CH3 O retro-aldol O retro-Michael O
CH3 H CH3
NH O NH O NH O
HO HO HO
O H O
O O O O-
8.20
-CO2 +H+
B-

O OH O
OH
OH

CH3O O OH H O
CH3 O
NH2
HO
doxorubicin
 Gene-Directed Enzyme Prodrug Therapy
(GDEPT)
Also known as suicide gene therapy
A gene encoding the prodrug-activating enzyme is
expressed in target cancer cells under the control of
tumor-selective promoters or by viral transfection.
These cells activate the prodrug as in ADEPT.
Cl Cl
OMe OMe

N nitroreductase H N OMe
OMe N
N HO N: H
O2N O H O OMe
OMe NMe
NMe
N O NH N O NH
-CO2
O O +H+

Cl
OMe

N
OMe
N
O H
OMe

NH2
amino-seco-CBI-TMI
8.21
Nitroreductase gene-directed enzyme
prodrug therapy
suicide gene therapy
suicide gene therapy
 4.Prodrug for Stability
protection from first-pass effect
Oral administration has lower bioavailability than
i.v. injection. O NHCH(CH3 )2
OR'

R
propanolol (R = R' = H)
8.22
antihypertension
O
prodrug R' = CCH2 CH2COOH
plasma levels 8 times that with propanolol
5.Prodrugs for Slow and Prolonged Release
1. To reduce the number and frequency of doses
2. To eliminate night time administration
3. To minimize patient noncompliance
4. To eliminate peaks and valleys of fast release
(relieve strain on cells)
5. To reduce toxic levels
6. To reduce GI side effects

#Long-chain fatty acid esters hydrolyze slowly
#Intramuscular injection is used also
 O OR
F N

Cl

haloperid ol (R = H)
haloperid ol decan oate (R = CO(CH2) 8CH3 )
8.24
Sedative/tranquilizer/antipsychotic
O
prodrug R' = C(CH2) 8CH3 slow release
inject i.m.
Antipsychotic activity for about 1 month
 6.Prodrugs to Minimize Toxicity

Many of the prodrugs just discussed also have
lowered toxicity.
For example, epinephrine (for glaucoma) has
ocular and systemic side effects not found in
dipivaloylepinephrine.
7.Prodrug to Increase Patient Acceptance
CH3
The antibacterial drug N H H
N Cl
clindamycin (8.28) is
bitter and not well H O HO
OH
O

tolerated by children. SCH3
OR
Clindamycin palmitate clindomycin (R = H)
is not bitter. clindomycin pho sphate (R = PO3H2)
clindomycin palmitate (R = O(CH 2) 1 4CH3 )
8.28

Either not soluble in saliva or does not bind to
the bitter taste receptor or both.
 8.Prodrug to Eliminate Formulation
Problems
Formaldehyde is a gas with a pungent odor that is used as a
disinfectant. Too toxic for direct use.
N

H+
CH2O + NH3 N N
H3O+ N

methenamine
8.30
It is a stable solid that decomposes in aqueous acid.
The pH of urine in the bladder is about 4.8, so methenamine is used as a
urinary tract antiseptic.
Has to be enteric coated to prevent hydrolysis in the stomach.
 Areas of Improvement for Prodrugs

site specificity
protection of drug from biodegradation
minimization of side effects
 Macromolecular Drug Delivery
To address these shortcomings, macromolecular drug
delivery systems have been developed.

A bipartate carrier-linked prodrug in which the drug is
attached to a macromolecule, such as a synthetic polymer,
protein, lectin, antibody, cell, etc.
Absorption/distribution depends on the physicochemical
properties of macromolecular carrier, not of the drug.
Therefore, attain better targeting.
Minimize interactions with other tissues or enzymes.
Fewer metabolic problems; increased therapeutic index.
 Disadvantages of Macromolecular
Delivery Systems

Macromolecules may not be well absorbed
Alternative means of administration may be
needed (injection)
Immunogenicity problems
 Macromolecular Drug Carriers
Synthetic polymers
CH2 CH CH2 CH
x y
OH O

O
O
8.32 O

Aspirin linked to poly(vinyl alcohol) has about the
same potency as aspirin, but less toxic.
 Steric Hindrance by Polymer Carrier
poly(methacrylate)
CH3 CH3
CH2 C CH2 C
x y
C=O C=O
O
O
to enhance
water
S=O solubility
O
testosterone 8.34

#No androgenic effect
#Polymer backbone may be sterically hindering
the release of the testosterone.
A spacer arm was added, and it was as effective
as testosterone. CH3 CH3
CH2 C CH2 C
x y
C=O C=O
O
O
to enhance
-
water
+ Cl
spacer NMe2 S=O solubility
arm
O H3 C

O

O
8.35
 Poly(-Amino Acid) Carriers
O
poly(L-glutamine) NH CH C
x
spacer
O
O N O O
H C CH

O
8.37
norethindrone - contraceptive

#Slow release over nine months in rats
General Site-Specific Macromolecular
Drug Delivery System
Polymer chain

Solubilizer spacer Homing
device

either hydrophilic
or hydrophobic Drug for site specificity
8.38
Site-Specific Delivery of a Nitrogen Mustard
O O O
NHCH C NH CH C
y
NHCH C
z
poly(L-Glu)
x
spacer
O
arm
O O
NH
O- NH

water-solubilizing Ig antibody from
rabbit antiserum
N against mouse
Cl Cl
lymphoma cells
8.39
All 5 mice tested were alive and tumor free after 60
days (all controls died).
Also, therapeutic index greatly enhanced (40 fold).
 Tumor Cell Selectivity
Drug attached to albumin (R = albumin)
NH2
Tumor cells take up
proteins rapidly. Proteins N
broken down inside cells,
O N
releasing the drug. RO
O
HO
Shown to inhibit growth
of Ectomelia virus in OH
mouse liver, whereas free cytosine arabinoside (R = H)
inhibitor did not. 8.41
antitumor
 Antibody-Targeted Chemotherapy
calicheamicin, except as disulfide
HO
instead of trisulfide
O

NH O
CH3O
H polysaccharide HO
O
O
CH3 S
H O
N S NH
CH3O
N H polysaccharide
H
N RS - O
O
antibody Lys O
S
O
gemtuz umab ozo gamicin
8.42 8.43

humanized spacer

Does not release calicheamicin nonenzymatically.
Exhibits no immune response.
 Tripartate Drugs
(Self-immolative Prodrugs)
A bipartate prodrug may be ineffective because the
linkage is too labile or too stable.
In a tripartate prodrug, the carrier is not attached to
the drug; rather, to the linker.
Therefore, more flexibility in the types of functional
groups and linkages that can be used, and it moves
the cleavage site away from the carrier.
The linker-drug bond must cleave spontaneously
(self-immolative) after the carrier-linker bond is
broken.
 Tripartate Prodrugs

enzyme
Carrier Linker Drug Carrier + Linker Drug

spontaneous

Linker + Drug
 Typical Approach

O
Drug—X—CH2 —O—CR esterase Drug—X—CH2 —O- + RCOOH

fast

Drug—X - + CH2O
 Tripartate Prodrugs of Ampicillin
O

Poor oral absorption (40%) NH
S
NH2
Excess antibiotic may destroy
N
important intestinal bacteria O
used in digestion and for COO-
biosynthesis of cofactors. ampicillin
8.44
Also, more rapid onset of antibacterial
resistance.

Various esters made were too stable in humans (although they were
hydrolyzed in rodents) - thought the thiazolidine ring sterically
hindered the esterase.
 Tripartate Prodrugs of Ampicillin

O O
Ph Ph
NH NH
S S
NH2 esterase NH2
+ R'COOH
N N
O O..
O O R' O OH when
O O R' = OEt
R O R
8.46
bacampicillin (R = CH 3 , R' = OEt) EtOH
pivampicillin (R = H, R' = t-Bu) O + CO2
8.45
R H

98-99% absorbed 8.44

Ampicillin is released in < 15 minutes
 hydrolysis
activated
hydrolysis deactivated
O O O

Drug—X crosses Drug—X enzyme Drug—X
blood-brain oxidation
N barrier N N+
CH3 CH3 CH3
8.48
8.47
hydrophilic HOOC enzyme
hydrolysis
drug + Drug — XH
electron-
N+
electron-donating, withdrawing;
CH3
lipophilic carrier 8.49
hydrophilic

Passive diffusion of 8.47 into the brain; active transport of 8.49
out of the brain
XH of the drug is NH2, OH, or COOH
If oxidation occurs before it gets into the brain, it cannot cross the
blood-brain barrier.
 When the drug is a carboxylic acid, a self-immolative reaction
also can be used.

O O O O
Drug C OCH2 O C carrier esterase Drug— C— O—CH2 —O- + HOC carrier

8.50 fast —CH2O

Drug—COO-
 Example of Redox Drug Delivery
Antibody generation in the brain is not significant.
-Lactams are too hydrophilic to cross the blood-brain
barrier effectively.
H
R N S H
R N S
O
O N enzymatic O
O O N
O O oxidation O
O O O
N O
N
Me
8.51 Me
esterase
H H
R N S N O
R S
-CH2O
O N O N O
O O
O-
O O N
O O Me
8.49
High concentrations of -lactams delivered into brain.
 Tripartate Prodrug for Delivery of
Antibacterials
Permeases are bacterial transport proteins for uptake
of peptides.
 Mutual Prodrugs
A bipartite or tripartite prodrug in which the carrier is
a synergistic drug with the drug to which it is linked.

Antibacterial -lactamase inactivator
ampicillin penicillanic acid sulfone
O
Ph
N O O
H S
NH2 S
N
O O O N
O O
O
sultamicillin
8.59
Hydrolysis gives 1:1:1 ampicillin : penicillanic acid sulfone :
formaldehyde
 Ideal Mutual Prodrugs
Well absorbed
Both components are released together
and quantitatively after absorption
Maximal effect of the combination of the
two drugs occurs at 1:1 ratio
Distribution/elimination of components
are similar
 II.Bioprecursor Prodrugs
Carrier-linked prodrugs largely use hydrolytic
activation
Bioprecursor drugs mostly use oxidative or
reductive activation

#The metabolically-activated alkylating
agents are actually examples of bioprecursor
prodrugs.
 Protonation Activation
Discovery of Omeprazole

Cimetidine and ranitidine reduce gastric acid
secretion by antagonizing the H2 histamine
receptor.
Another way to lower gastric acid secretion is by
inhibition of the enzyme H+,K+-ATPase (also
called the proton pump), which exchanges
protons for potassium ions in parietal stomach
cells, thereby increasing stomach acidity.
 Lead Discovery
Lead compound found in a random screen.

S

N NH2
8.60

Liver toxicity observed thought to be because of
the thioamide group.
 Lead Modification
Related analogs made, and 8.61 had good antisecretory
activity. N
S
N
N
8.61 H

Modification gave 8.62 with high activity.
N
S
N
N
8.62 H

The sulfoxide (8.63) was more potent, but it blocked
iodine uptake into the thyroid.
O
N
S
N
N
H
timoprazole
8.63
 Lead Modification (cont’d)
CH3
Modification of 8.63 gave O
N CO2CH3
8.64 having no iodine N
S

blockage activity. N
H
CH3
picopraz ole
8.64
Picoprazole shown to be an
inhibitor of H+,K+-ATPase.
SAR of analogs indicated OCH3
CH3
electron-donating groups on H3 C O
N OCH3
the pyridine ring were S
N
favorable. Increased inhibition N
H
of H+,K+-ATPase. omepraz ole
Best analog was omeprazole 8.65

(8.65).
The pKa of the pyridine ring of omeprazole is about 4, so it is
not protonated and able to cross the secretory canaliculus of the
parietal cell. The pH inside the cell is below 1, so this initiates
the protonation reaction below.
OCH3 OCH3 OCH3 OCH3
H3 C CH3 CH3 CH3 CH3
H3 C H3 C H3 C

N -H2 O.. N N N
S
S.. S S
O HN S HN
HN O OH N N
N N
N H
H+

OCH3 OCH3 OCH3
OCH3
8.66
omepraz ole
8.65
+H+

OCH3
H3 C CH3

Formation of 8.66 leads to covalent attachment. N
Omeprazole also inhibits isozymes of carbonic N
S
S
NH
anhydrase, another mechanism for lowering gastric
acid secretion.
OCH3
 Hydrolytic Activation
Hydrolysis can be a mechanism for bioprecursor
prodrug activation, if the product requires additional
activation.
R
Me S
O S O- Me S
O- O
S+ N N S+ N
S H N
Me
K2CO3/RX HO O
O Me OH

Me HO O Me
HO O
leinamycin
8.70 8.71
antitumor agent prodrugs of leinamycin
HO- O Hydrolysis of these analogs gives an intermediate
Me
O
O that reacts further to the activated form.
S- O Me S
S Me O-
O O- Me S O O- S
S+ N N
S+ N S+ N S H
N N
Me Me
HO O HO O O Me OH DNA
cleavage

Me O
Me Me O
O O O O
O
this was
O
O
synthesized and
8.72
8.73
gave 8.74 as well
increased stability as DNA cleavage
Me
over leinamycin HO2 C
O S

N N
Me H
HO S

HO Me
O O

O

8.74
 Elimination Activation

CF 3 CF 3
B: O
O
H N
N C
H N
H
N
O CH3
HO CH3
H
B 8.76 potent inhibitor of
leflunom ide
8.75
dihydroorotate
rheumatoid arthritis drug dehydrogenase

Inhibition of dihydroorotate dehydrogenase blocks
pyrimidine biosynthesis in human T lymphocytes.
 Oxidative Activation
N-Dealkylation
Sedative
CH3 CH3 CH3
N N N
N N N N
N N
CH3 P450 CH3 P450 NH.. 2
O N N O
Cl O
CH3 Cl H Cl
X X X

CH3 N CH3 N
N
N N
-H2 O N

Cl N..
Cl NH
HO X
X

alpraz oalam (X = H)
triaz olam (X = Cl)
8.77
 O-Dealkylation
Analgesic activity of phenacetin is a result
of O-dealkylation to acetaminophen.
O

HN CH3

OR
phenacetin (R = C H2 CH3 )
acetaminophen (R = H)
8.78
 Oxidative Deamination
Neoplastic (cancer) cells have a high concentration of
phosphoramidases, so hundreds of phosphamide analogs of
nitrogen mustards were made for selective activation in these cells.
HO:
H H O
N P-450 N H NH
O O 2
P Cl P Cl H P O
O N O N O Cl
N
B:
Cl Cl Cl
cyclophosphamide 8.80 8.81
8.79

H 2N O
- P O
O Cl
Cl spontaneous N H
HPO4= + NH3 + HN or +
phosphoramidase Cl
Cl 8.83
Cyclophosphamide was very 8.84 8.82

effective, but it required liver DNA DNA

homogenates (contains P450) O H
N
O H
N
+ OH OH
for activation. Therefore HN N HN N

N N
oxidation is required, not H 2N N
DNA
H 2N N

hydrolysis.
8.86
8.85
isolated
 N-Oxidation
identified
O O O
P450 -H2 O
CH3 NHNHCH2 CNHCHMe 2 CH3 NHNHCH2 CNHCHMe 2 CH3N=N—CH CNHCHMe 2
+
HO B—H H
procarbaz ine 8.88
8.87 B:

advanced Hodgkin’s
disease O O
H2O
CH3N-NH2 + OHC CNHCHMe 2 CH3N-N=CH CNHCHMe 2
H H

8.89

CH3N=NH
O CH3 O CH3
+ +N
CH3-N N N
DNA HN HN

CH3 + N2 H2N N N H2N N N
DNA

Scheme 8.22
8.90

identified
 N-Oxidation
Pralidoxime chloride is an antidote for nerve
poisons.
It reacts with acetylcholinesterase that has been
inactivated by organophosphorus toxins.

N OH
-
+N
Cl
CH3
pralidoxime chloride
8.91
 To increase the permeability of pralidoxime into
the CNS, the pyridinium ring was reduced (8.92).
N OH
N
CH3
8.92

oxidation into brain

N OH
-
+N
Cl
CH3
pralidoxime chloride
8.91
Similar to the reversible redox drug delivery strategy for getting drugs
into the brain by attaching them to a dihydronicotinic acid,
hydrophobic 8.92 crosses the blood-brain barrier; oxidation to 8.91
prevents efflux from brain.
 Prodrugs for (increased) Site Specificity
✵Bodor and co-workers have devised a reversible redox drug
delivery system (RRDDS) for getting drugs into the CNS and
then, once in, preventing their efflux.

The approach is based on the attachment of a hydrophilic drug to a
lipophilic carrier (a dihydropyridine) thereby making prodrug
that actively transported into the brain.

O H H
O H H R
R X
X
N
N
CH3
CH3 Blood-brain
Prodrug residue barrier
 Prodrugs for (increased) Site Specificity
Once inside the brain, the lipophilic carrier is
converted enzymatically to a highly
hydrophilic species (positively charged), which
O H
is then enzymatically hydrolyzed back to the H
R
drug and N-methylnicotinic acid, which is X
eliminated from the brain.
N
CH3
♫The oxidation of the dihydropyridine to the Enzymatic oxidation
pyridinium ion (half-life generally 20-50 min)
O
prevents the drug from escaping out of the R
brain because it becomes charged. X

♫This drives the equilibrium of the lipophilic N

precursor throughout all of the tissues of the CH3

body to favor the brain.
Prodrugs for (increased) Site Specificity

O H H
O H H R
R X
X
N
N
CH3
CH3 Blood-brain Enzymatic oxidation
Prodrug residue barrier

O
HOOC R
Drug release
HX R X
+ Drug by a suitable
N process
N
CH3
CH3
Mechanism of Acetylcholinesterase

O
Me 3N—CH2CH2—O Me 3N—CH2CH2—OH
Trp H CH3 Trp O
Phe Trp Trp +
B+ H :B Phe B: HB
O CH3
O

H2O

+
Me 3NCH2CH2OH + CH3 COOH
 Inactivation of Acetylcholinesterase by
Diisopropyl Phosphorofluoridate
Scheme 8.24
affinity labeling agent
O O O O
F P
Trp P
H O Trp O
Phe Trp B+ :B O
H Phe Trp B HB
O

8.93
irreversible inhibition
Inactivation prevents degradation of the excitatory
neurotransmitter acetylcholine. Accumulation of
acetylcholine causes muscle cells in airways to contract
and secrete mucous, then muscles become paralyzed.
 Reactivation of Inactivated
Acetylcholinesterase by Pralidoxime
Scheme 8.25
O O H O
N N O
P O:
Trp pralidoxime P
O Trp Me O
O
Phe Trp B HB Phe Trp
O
B HB

O
O N O
N O P
O
N P O Trp Me
N O
Me O Phe Trp BH OH :B
 Temporary inhibition of acetylcholinesterase
enhances cholinergic action on skeletal muscle.
Scheme 8.26
O
Me 3N O Me 3N OH
Trp H NMe2 Trp O +
Phe Trp B+ :B Trp B: HB
H Phe
O NMe2
O

neostigmine covalent, but
8.94
reversible slow H2O
Used for the neuromuscular
inhibition
disease myasthenia gravis
+ CO2 + Me2NH
Me 3N OH
 Reversible (noncovalent) inhibitors of
acetylcholinesterase, such as donepezil and tacrine
are used for Alzheimer’s disease. Enhances
neurotransmission involved in memory.
O
H3CO NH2

H3CO
N
N.. HCl HCl
donepez il hydrochloride tacrine hydrochloride
8.95 8.96
 S-Oxidation
Poor oral bioavailability of brefeldin A. Converted to
Michael addition sulfide prodrug (8.98). S-Oxidation
and elimination gives brefeldin A.
Scheme 8.27
:B
H HO H HO H HO H H
O O
HO RSH [O] O
O CH3 HO RS H HO RS
O CH3 H O CH3
H H O
H
brefeldin A
8.97 8.98
8.99

-RSOH

antitumor,
antiviral agent
 Aromatic Hydroxylation
Cyclohexenones as prodrugs for catechols
Scheme 8.28

N -H2 O N N
P450 N

HO
O O OH
O
P450
8.100 aromatic hydroxylation
oxidation next to
sp2 carbonyl N

HO
OH
8.101
 Alkene Epoxidation

O

N
N
O NH2
O NH2
carbamaz epine
8.102 8.103
active anticonvulsant agent
 Transamination
Stimulation of pyruvate dehydrogenase results in a
change of myocardial metabolism from fatty acid
to glucose utilization.
Glucose metabolism requires less O2 consumption.
Therefore, utilization of glucose metabolism would
be beneficial to patients with ischemic heart
disease (arterial blood flow blocked; less O2
available).
Arylglyoxylic acids (8.104) stimulate pyruvate
dehydrogenase, but have a short duration of action.
O

COOH

R
8.104

Oxfenicine (8.105, R = OH) is actively transported and is
transaminated (a PLP aminotransferase) in the heart to
8.104 (R = OH).
NH 2

COOH

R
oxfenicine (R = OH)
8.105
 Reductive Activation
Azo Reduction
Scheme 8.29
COOH

NHSO2 N=N OH Anaerobic cleavage
N
by bacteria in lower
sulfasalazine
8.106 bowel
ulcerative colitis COOH

H2N OH + NHSO2 NH2
N
8.107 sulfapyridine
8.108
For inflammatory Causes side effects
bowel disease
To prevent side effect by sulfapyridine a
macromolecular delivery system was developed.
n poly(vinylamine)
NH
SO2
Not absorbed or
metabolized in small
spacer CO2Na
intestine.
N N OH

8.109
CO2Na

NH2 OH
Released by reduction at the disease site.

Sulfapyridine is not released (still attached to polymer).
More potent than sulfasalazine.
 Azido Reduction
R
N
N

N N
HO
O
OH

HO
vidarabine (R = NH2)
8.110
antiviral drug

Vidarabine is rapidly deaminated by adenosine deaminase. 8.110, R =
N3 is not a substrate for adenosine deaminase and also can cross the
blood-brain barrier for brain infections.
 Sulfoxide Reduction
CO2H
F
CH3

CH3 S
O
sulindac
8.111
anti-arthritis
Sulindac is inactive in vitro; the sulfide is active in
vitro and in vivo.
Sulindac is an indane isostere of indomethacin, which was designed
as a serotonin analog.
The 5-F replaced the 5-OMe group to increase analgesic properties.
The p-SOCH3(sulfine) group replaced p-Cl to increase water solubility.

CO2H CO2H
F MeO
CH3 CH3
N NH2

O HO

CH3 S N
Cl H
O
indometh acin serotonin
sulindac 8.112
8.111
 Disulfide Reduction
To increase the lipophilicity of thiamin for absorption into
the CNS.
OH OH
Scheme 8.30..
N GSH N
N S S O N S-
O H O H
CH3 N NH2 CH3 N NH2
+B H
8.113

nonenzymatic

OH
+ N:
N N OH N S
S
CH3 N NH2 CH3 N NH2 OH

thiamin
8.114
poorly absorbed into CNS
CH3O
To diminish toxicity of primaquine and
target it for cells with the malaria parasite, a
N
HN macromolecular drug delivery system was
NH2
designed.
primaquine
8.115
antimalarial, toxic Intracellular thiol much higher than
in blood; selective reduction inside
the cell
CH3O
lactose

N O
HN serum
N S S
H albumin
NH 3+

primaquine 8.116 for lactose
improved
uptake in liver
Therapeutic index of 8.116 is 12 times higher than 8.115 in mice.
 Nitro Reduction
Scheme 8.32
O O O
F F Cl F
HN HN HN
O O O
Cl Cl
N P O O N bioreductio n O..
N P O N N P O O N
H3 C O O H3 C O O O
H3 C O-

HO HO HO
O O
8.120
O2N..
8.118 HO NH 8.119

O O O
F F F
HN HN HN
O O
O
-O O N H2O P O O N N P O O N
P O
O O O H3 C O- O
O-

HO HO HO
8.121

Mechanism-based inactivator of
thymidylate synthase
 Nucleotide Activation
Scheme 8.33
=O
SH
3PO O O O
SH N N
O—P—O—P—O-
N N N N
HO OH O -
O - =
O3PO O
N N hypoxanthine-guanine
H phosphorib osyltransferase
6-mercaptopurine HO OH
8.122
Anti-leukemia drug 8.123
Inhibits several enzymes in
the purine nucleotide
biosynthesis pathway.
 Phosphorylation Activation
O
O N
HN
HN N
H 2N N N
H2N N N HO
RO O
O
HO
acyclovir (R = H)
8.124 8.125
antiviral 2-deoxyguanosine
Resembles structure of 2-deoxyguanosine
viral thymidine kinase
Uninfected cells do not R = PO3=
phosphorylate acyclovir
(selective toxicity) viral guanylate kinase
R = P2O6-3
viral phosphoglycerate kinase
R = P3O9-4
Acyclovir triphosphate is a substrate for viral -DNA
polymerase but not for normal -DNA polymerase
Incorporation into viral DNA leads to a dead-end
complex (not active). Disrupts viral replication cycle
and destroys the virus.
Even if the triphosphate of acyclovir were released, it
is too polar to be taken up by normal cells.
High selective toxicity
Only 15-20% of acyclovir is absorbed
Therefore, prodrugs have been designed to
increase oral absorption.
Hydrolyzes NH2
here Prodrug for
N N
a prodrug
H2N N N
HO
O

8.126
adenosine deaminase

acyclovir
Hydroxylates
here
N
N
H 2N N N
HO
O

8.127

xanthine oxidase

acyclovir
A bipartate carrier-linked prodrug of acyclovir,
the L-valyl ester of acyclovir, has 3-5 fold higher
oral bioavailability with the same safety profile.
O

HN N

H 2N H 2N N N
O
O
O

valaciclovir
8.128
An analog of acyclovir whose structure is even
closer to that of 2-deoxyguanosine is ganciclovir.
O

HN N

H 2N N N
HO
O

HO
ganciclovir
8.129

More potent than acyclovir against human
cytomegalovirus.
Two carbon isosteres of ganciclovir are available.
O
N N N
HN
H 2N N H 2N N N
N
HO AcO

C in place AcO
C in place
HO
of O of O
penciclovir famciclovir
8.130 8.131

Better oral absorption
than penciclovir
Converted to penciclovir
rapidly
 Sulfation Activation
Activity of minoxidil requires sulfotransferase-catalyzed
sulfation to minoxidil sulfate.
OR
H2N N NH2

N

N

minoxidil (R = )
minoxidil sulfate (R = SO3- )
8.132
hair growth
Inhibitors of the sulfotransferase inhibit the activity of
minoxidil, but not minoxidil sulfate.
 Decarboxylation Activation
An imbalance in the inhibitory neurotransmitter
dopamine and the excitatory neurotransmitter
acetylcholine produces movement disorders, e.g.
Parkinson’s disease.
In Parkinson’s there is a loss of dopaminergic neurons
and a low dopamine concentration.
Dopamine treatment does not work because it cannot
cross blood-brain barrier, but there is an active transport
system for L-dopa (levodopa, 8.133, R = COOH).
 HO

HO
NH2
H R
levodop a (R = COOH)
8.133

After crossing blood- L-aromatic amino acid
brain barrier decarboxylase (PLP)

dopamine (R = H)

Does not reverse the disease, only slows progression.
 Combination Therapy
Monoamine oxidase B (MAO B) degrades
dopamine in the brain.
Therefore, a MAO B-selective inactivator is used
to protect the dopamine - selegiline (L-deprenyl).
Peripheral L-aromatic amino acid decarboxylase
destroys >95% of the L-dopa in the first pass.
Maybe only 1% actually gets into brain.
To protect L-dopa from peripheral (but not CNS)
degradation, inhibit peripheral L-aromatic amino
acid decarboxylase with a charged molecule that
does not cross the blood-brain barrier.
HO
HO OH
HO O NH2
NHNH3+ HO
H3 C N N OH
COO- H H
carbidopa benseraz ide
8.134 8.135
(used in U.S.) (used in Europe and Canada)
Selectively inhibits peripheral L-amino acid
decarboxylase.
The dose of L-dopa can be reduced by 75%.
 Selective Inactivation of Brain
Monoamine Oxidase A
Earlier we found that inactivation of brain MAO A has an
antidepressant effect, but a cardiovascular side effect
occurs from inactivation of peripheral MAO A.
8.136 (R = COOH) is actively transported into the brain,
where L-aromatic amino acid decarboxylase converts it to
8.136 (R = H), a selective MAO A mechanism-based
inactivator. Carbidopa protects 8.136 (R = COOH) from
decarboxylation outside of the brain.
F

NH 2

R

OH
8.136
 Selective Delivery of Dopamine to Kidneys
Dopamine increases renal blood flow.
Prodrugs were designed for selective renal vasodilation.
Scheme 8.34 OH
OH
COO- L--glutamyl
H transpeptidase
+ N OH + OH
NH3 NH3
O COO- COO-
Glu
8.137 L-dopa
L--glutamyl-L-dopa L-aromatic amino acid
decarboxylase
+
Dopamine accumulates in the kidneys because of NH3 OH
high concentrations of L--glutamyltranspeptidase
and L-aromatic amino acid decarboxylase there. OH