Stereochemistry: Chiral Molecules PDF

Summary

This document provides an introduction to stereochemistry, focusing on chiral molecules. It explains how the three-dimensional arrangements of atoms influence properties and describes the biological importance of chirality in drug development examples like thalidomide are given.

Full Transcript

Chapter 5

Stereochemistry
Chiral Molecules

Chapter 5
In this chapter we will consider:
 How to identify, codify, and name the
three-dimensional arrangement of
atoms and molecules

 How such arrangements can lead to
unique properties and behaviors

Chapter 5
1. Chirality & Stereochemistry

 An object is achiral (not chiral) if the
object and its mirror image are
identical

Chapter 5
 A chiral object is one that cannot be
superposed on its mirror image

Chapter 5
1A. The Biological Significance of
Chirality
 Chiral molecules are molecules that
cannot be superposed onto their mirror
images
O O One enantiomer
NH causes birth defects,
N O the other cures
morning sickness
O
Thalidomide
Chapter 5
 HO

NH
HO
OMe
Tretoquinol
OMe
OMe

One enantiomer is a bronchodilator, the
other inhibits platelet aggregation

Chapter 5
 66% of all drugs in development are
chiral, 51% are being studied as a single
enantiomer

 Of the $475 billion in world-wide sales of
formulated pharmaceutical products in
2008, $205 billion was attributable to
single enantiomer drugs

Chapter 5
2. Isomerism: Constitutional
Isomers & Stereoisomers
2A. Constitutional Isomers
 Isomers: different compounds that
have the same molecular formula
Constitutional isomers: isomers
that have the same molecular
formula but different connectivity –
their atoms are connected in a
different order
Chapter 5
 Examples
Molecular Constitutional
Formula Isomers

C4H10 and
Butane 2-Methylpropane

Cl
C3H7Cl Cl
and
1-Chloropropane 2-Chloropropane
Chapter 5
 Examples
Molecular Constitutional
Formula Isomers

OH and CH3 O CH3
C2H6O
Ethanol Methoxymethane

O
OCH3
OH and
C4H8O2
O
Butanoic acid Methyl propanoate
Chapter 5
2B. Stereoisomers

 Stereoisomers are NOT constitutional
isomers

 Stereoisomers have their atoms
connected in the same sequence but
they differ in the arrangement of their
atoms in space. The consideration of
such spatial aspects of molecular
structure is called stereochemistry
Chapter 5
2C. Enantiomers & Diastereomers
 Stereoisomers can be subdivided into
two general categories:
enantiomers & diasteromers
Enantiomers – stereoisomers
whose molecules are
nonsuperposable mirror images of
each other
Diastereomers – stereoisomers
whose molecules are not mirror
images of each other
Chapter 5
 Geometrical isomers
(cis & trans isomers) are:
Diastereomers
e.g.
Ph
Ph Ph and Ph
(cis) (trans)

Cl Cl Cl H
and
H H H Cl
(cis) (trans)
Chapter 5
Subdivision of Isomers
Isomers
(different compounds with same
molecular formula)

Constitutional Isomers Stereoisomers
(isomers whose atoms (isomers that have the same
have a different connectivity but differ in spatial
connectivity) arrangement of their atoms)

Enantiomers Diastereomers
(stereoisomers that are (stereoisomers that are
nonsuperposable mirror NOT mirror images of
images of each other) each other)

Chapter 5
3. Enantiomers and Chiral
Molecules
 Enantiomers occur only with compounds
whose molecules are chiral
 A chiral molecule is one that is NOT
superposable on its mirror image
 The relationship between a chiral
molecule and its mirror image is one
that is enantiomeric. A chiral
molecule and its mirror image are said
to be enantiomers of each other
Chapter 5
 OH
(2-Butanol)

(I) and (II) are
nonsuperposable
H OH HO H mirror images of
each other
(I) (II)

Chapter 5
4. Molecules Having One Chirality
Center Are Chiral
 A chirality center is a tetrahedral
carbon atom that is bonded to four
different groups

 A molecule that contains one chirality
center is chiral and can exist as a pair
of enantiomers

Chapter 5
 The presence of a single chirality
center in a molecule guarantees that
the molecule is chiral and that
enantiomeric forms are possible

 An important property of enantiomers
with a single chirality center is that
interchanging any two groups at the
chirality center converts one
enantiomer into the other

Chapter 5
 Any atom at which an interchange of
groups produces a stereoisomer is
called a stereogenic center (if the
atom is a carbon atom it is usually
called a stereogenic carbon)
 If all of the tetrahedral atoms in a
molecule have two or more groups
attached that are the same, the
molecule does not have a chirality
center. The molecule is superposable
on its mirror image and is achiral
Chapter 5
 Cl
Me C* Et
H

same H Cl Cl H
as Me Et Et Me
(III) (IV)

mirror
(III) and (IV) are nonsuperposable
mirror images of each other
Chapter 5
 same
as

mirror
(V) and (VI) are superposable
⇒ not enantiomers ⇒ achiral
Chapter 5
4A. Tetrahedral vs. Trigonal
Stereogenic Centers
 Chirality centers are tetrahedral
stereogenic centers
H OH HO H
Me * Et Et * Me
(A) (B)
Tetrahedral
stereogenic (A) & (B) are
center mirror
enantiomers
⇒ chiral
Chapter 5
 Cis and trans alkene isomers contain
trigonal stereogenic centers

Ph H H Ph

H Ph Ph H
Trigonal (C) (D)
stereogenic mirror
center
⇒ achiral (C) & (D) are identical

Chapter 5
5. More about the Biological
Importance of Chirality

Chapter 5
Thalidomide
 The activity of drugs containing
chirality centers can vary between
enantiomers, sometimes with serious
or even tragic consequences

 For several years before 1963
thalidomide was used to alleviate the
symptoms of morning sickness in
pregnant women
Chapter 5
 In 1963 it was discovered that thalidomide
(sold as a mixture of both enantiomers) was
the cause of horrible birth defects in many
children born subsequent to the use of the
drug
O O O O
NH NH
N O N O

O O
Thalidomide enantiomer of
(cures morning sickness) Thalidomide
(causes birth defects)
Chapter 5
6. How to Test for Chirality:
Planes of Symmetry
 A molecule will not be chiral if it
possesses a plane of symmetry
 A plane of symmetry (mirror plane) is an
imaginary plane that bisects a molecule
such that the two halves of the molecule
are mirror images of each other
 All molecules with a plane of symmetry
in their most symmetric conformation
are achiral
Chapter 5
Plane of symmetry
Cl

Me Me

H
achiral

Cl
No plane of
Me Et
symmetry
H
chiral
Chapter 5
7. Naming Enantiomers:
The R,S -System
OH H OH HO H
Recall:
(I) (II)

 Using only the IUPAC naming that we have
learned so far, these two enantiomers will
have the same name:
2-Butanol
 This is undesirable because each compound
must have its own distinct name
Chapter 5
7A. How to Assign (R) and (S)
Configurations
 Rule 1
Assign priorities to the four different
groups on the stereocenter from
highest to lowest (priority bases on
atomic number, the higher the
atomic number, the higher the
priority)

Chapter 5
 Rule 2
When a priority cannot be assigned
on the basis of the atomic number
of the atoms that are directly
attached to the chirality center, then
the next set of atoms in the
unassigned groups is examined.
This process is continued until a
decision can be made.

Chapter 5
 Rule 3
Visualize the molecule so that the
lowest priority group is directed
away from you, then trace a path
from highest to lowest priority. If
the path is a clockwise motion, then
the configuration at the asymmetric
carbon is (R). If the path is a
counter-clockwise motion, then the
configuration is (S)
Chapter 5
 HO H
 Example (2-Butanol)

① ④
O H
Step 1:
C C
② or ③ ② or ③

① ④
O H
Step 2: ③ C ② CH
3
H3C C
H2
(H, H, H) (C, H, H)
Chapter 5
 ① OH
OH
④
H
③ ②
Me Et Et
Me
OH
OH H
HO
= H
Me Et
Me Et Et
Arrows are clockwise Me

(R)-2-Butanol
Chapter 5
 Other examples
①
Cl Cl Counter-
④ clockwise
③
H CH3 HO CH3 (S)
HO
②
Clockwise
②
OCH3 OCH3
④
③ (R)
H 3C CH2CH3 Br CH2CH3
Br
①
Chapter 5
 Other examples
Rotate C–Cl bond such that H is pointed
to the back
②
Cl Cl
④
③
Br H H OH
HO ① Br

Cl Clockwise

Br OH (R)
Chapter 5
 Other examples
Rotate C–CH3 bond such that H is
pointed to the back
②
H OCH3
④
I H ①
OCH3 I
H3C H 3C ③

Counter-clockwise
OCH3

H3C I (S)
Chapter 5
 Rule 4
For groups containing double or
triple bonds, assign priorities as if
both atoms were duplicated or
triplicated
e.g. C O as C O
O C

C C as C C
C C
C C
C C as C C
C C
Chapter 5
 Example ③
CH3
④ (S)
H ②
CH=CH 2
HO ①
Compare CH3 & CH CH2 :
H H
CH CH2 equivalent to C C H
C C
Thus, CH3  (H, H, H)

CH CH2  (C, C, H)
Chapter 5
 Other examples
② (R)
OH
④ ③ CH3
H
Cl ① O
③ OH
H2C
④ ② C  (O, O, C)
② CH3
H
① Cl O (S) ③
C  (O, H, H)

Chapter 5
8. Properties of Enantiomers:
Optical Activity
 Enantiomers
Mirror images that are not
superposable
H H
* *
Cl CH3 H3C Cl
H3CH2C CH2CH3

mirror
Chapter 5
 Enantiomers have identical physical
properties (e.g. melting point, boiling
point, refractive index, solubility etc.)
Compound bp (oC) mp (oC)
(R)-2-Butanol 99.5
(S)-2-Butanol 99.5
(+)-(R,R)-Tartaric Acid 168 – 170
(–)-(S,S)-Tartaric Acid 168 – 170
(+/–)-Tartaric Acid 210 – 212
Chapter 5
 Enantiomers
Have the same chemical properties
(except reaction/interactions with
chiral substances)
Show different behavior only when
they interact with other chiral
substances
Rotate plane-polarized light in
opposite direction

Chapter 5
 Optical activity
The property possessed by chiral
substances of rotating the plane of
polarization of plane-polarized light

Chapter 5
8A. Plane-Polarized Light
 The electric field (like the magnetic
field) of light is oscillating in all
possible planes
 When this light passes through a
polarizer (Polaroid lens), we get plane-
polarized light (oscillating in only one
plane)
Polaroid
lens
Chapter 5
8B. The Polarimeter
 A device for measuring the optical
activity of a chiral compound

a = observed
optical rotation

Chapter 5
8C. Specific Rotation
observed
temperature rotation
25 a
[a]D =
c x ℓ
wavelength
concentration length of cell
of light
of sample in dm
(e.g. D-line
solution (1 dm = 10 cm)
of Na lamp,
in g/mL
l=589.6 nm)

Chapter 5
 The value of a depends on the
particular experiment (since there are
different concentrations with each run)
But specific rotation [a] should be
the same regardless of the
concentration

Chapter 5
 Two enantiomers should have the
same value of specific rotation, but the
signs are opposite
CH3 CH3
* *
H CH2CH3 H3CH2C H
HO OH

25 o 25 o
[a] = + 13.5 [a] =  13.5
D mirror D

Chapter 5
9. The Origin of Optical Activity

Chapter 5
9. The Origin of Optical Activity

Chapter 5
9. The Origin of Optical Activity

Chapter 5
9A. Racemic Forms
 An equimolar mixture of two enantiomers
is called a racemic mixture (or racemate
or racemic form)
 A racemic mixture causes no net rotation
of plane-polarized light equal & opposite
rotation by the
rotation enantiomer

CH3 H 3C
H OH HO H
C2 H 5 C2H 5
(R)-2-Butanol (S)-2-Butanol
(if present)

Chapter 5
9B. Racemic Forms and Enantiomeric
Excess
 A sample of an optically active
substance that consists of a single
enantiomer is said to be
enantiomerically pure or to have an
enantiomeric excess of 100%

Chapter 5
 An enantiomerically pure sample of (S)-(+)-
2-butanol shows a specific rotation of
+13.52
25
[a]D = +13.52

 A sample of (S)-(+)-2-butanol that contains
less than an equimolar amount of (R)-(–)-2-
butanol will show a specific rotation that is
less than 13.52 but greater than zero
 Such a sample is said to have an
enantiomeric excess less than 100%
Chapter 5
 Enantiomeric excess (ee)
Also known as the optical purity

Can be calculated from optical
rotations
% enantiomeric observed specific rotation
= x 100
excess * specific rotation of the
pure enantiomers
Chapter 5
 Example
A mixture of the 2-butanol
enantiomers showed a specific
rotation of +6.76. The
enantiomeric excess of the (S)-(+)-
2-butanol is 50%

% enantiomeric +6.76
= x 100 = 50%
excess * +13.52

Chapter 5
10. The Synthesis of Chiral
Molecules
10A. Racemic Forms
Ni
CH3CH2CCH 3 + H H (
)-CH3CH2CHCH 3
O OH

Butanone Hydrogen (
 )-2-Butanol
(achiral (achiral (chiral
molecules) molecules) molecules; but
50:50 mixture
(R) & (S))
Chapter 5
Chapter 5
10B. Stereoselective Syntheses
 Stereoselective reactions are reactions
that lead to a preferential formation of one
stereoisomer over other stereoisomers that
could possibly be formed
enantioselective – if a reaction
produces preferentially one enantiomer
over its mirror image
diastereoselective – if a reaction
leads preferentially to one diastereomer
over others that are possible

Chapter 5
 O +
O
H , H2O
OEt heat OH + EtOH
F F
racemate ( 
) racemate ( 
)

O O
H2O
OEt lipase OH
F F
racemate ( 
) ()
(> 69% ee)
O
+ OEt + EtOH
F
(+)
(> 99% ee)
Chapter 5
11. Chiral Drugs
 Of the $475 billion in world-wide sales of
formulated pharmaceutical products in
2008, $205 billion was attributable to single
enantiomer drugs

Chapter 5
Chapter 5
12. Molecules with More than One
Chirality Center

 In compounds with n tetrahedral
stereocenters, the maximum number
of stereoisomers is 2n

Chapter 5
12A. How to Draw Stereoisomers for
Molecules Having More than One
Chirality Center

Chapter 5
 Start by drawing the portion of the
carbon skeleton that contains the
chirality centers in such a way that as
many of the chirality centers are placed
in the plane of the paper as possible,
and as symmetrically as possible

Chapter 5
 Next we add the remaining groups that
are bonded at the chirality centers in
such a way as to maximize the
symmetry between the chirality centers

Chapter 5
 To draw the enantiomer of the first
stereoisomer, we simply draw its mirror
image

Chapter 5
 To draw another stereoisomer, we
interchange two groups at any one of
the chirality centers
All of the possible stereoisomers for a
compound can be drawn by successively
interchanging two groups at each chirality
center

Chapter 5
 Next we examine the relationship
between all of the possible pairings of
formulas to determine which are pairs
of enantiomers, which are
diastereomers

Chapter 5
 Structures 1 and 2 are enantiomers;
structures 3 and 4 are also enantiomers
 Structures 1 and 3 are stereoisomers and they
are not mirror images of each other. They are
diastereomers
Diastereomers have different physical
properties - different melting points and
boiling points, different solubilities, and so
forth
Chapter 5
 Diastereomers
Stereoisomers that are not
enantiomers

Unlike enantiomers, diastereomers
usually have substantially different
chemical and physical properties

Chapter 5
 Br Br
(I) Cl C H H C Cl
(II)
HO C H H C OH
CH3 CH3

Br Br
Cl C H H C Cl
(III) (IV)
CH3 C H H C CH3
HO OH
 (I) & (II) are enantiomers of each other
 (III) & (IV) are enantiomers of each
other
Chapter 5
 Br Br
(I) Cl C H H C Cl
(II)
HO C H H C OH
CH3 CH3

Br Br
Cl C H H C Cl
(III) (IV)
CH3 C H H C CH3
HO OH
 Diastereomers of each other:
(I) & (III), (I) & (IV), (II) & (III),
(II) & (IV)
Chapter 5
12B. Meso Compounds
 Compounds with two stereocenters do
not always have four stereoisomers
(22 = 4) since some molecules are
achiral (not chiral), even though they
contain stereocenters
 For example, 2,3-dichlorobutane has
two stereocenters, but only has 3
stereoisomers (not 4)

Chapter 5
 H H
CH3 C Br Br C CH
(I) 3 (II)
CH3 C Br Br C CH3
H H

H H
CH C Br Br C CH
(III) 3 3 (IV)
H C Br Br C H
CH3 CH3
Note: (III) contains a plane of symmetry,
is a meso compound, and is achiral
([a] = 0o).
Chapter 5
 H H
CH3 C Br Br C CH
(I) 3 (II)
CH3 C Br Br C CH3
H H

H H
CH C Br Br C CH
(III) 3 3 (IV)
H C Br Br C H
CH3 CH3
 (I) & (II) are enantiomers of each
other and chiral
 (III) & (IV) are identical and achiral
Chapter 5
 H H
CH3 C Br Br C CH
(I) 3 (II)
CH3 C Br Br C CH3
H H

H H
CH C Br Br C CH
(III) 3 3 (IV)
H C Br Br C H
CH3 CH3
 (I) & (III), (II) & (III) are diastereomers
 Only 3 stereoisomers:
(I) & (II) {enantiomers}, (III) = (IV)
{meso} Chapter 5
12C. How to Name Compounds with
More than One Chirality Center
a
H Br
 2,3-Dibromobutane Br H b

2 3

1 4
Look through C2–Ha bond
a④
① Br H
③ 2 ②
C2: (R) configuration C1 C3

(H, H, H) (Br, C, H)
Chapter 5
 Look through C3–Hb bond
④
Br b ① b
H
H Br
a
H
3 4 ③ 3 ②
2 CH3 C4 C2
Br
1
CH3 (H, H, H) (Br, C, H)
C3: (R) configuration

Full name:
 (2R, 3R)-2,3-Dibromobutane

Chapter 5
13. Fischer Projection Formulas
13A. How To Draw and Use Fischer
Projections
Fischer
Projection
COOH COOH
Et Br
HO Ph Br Ph Br Ph
Et OH Et OH
H3C COOH
CH3 CH3
Chapter 5
 H Me
COOH Me OH
H H
Ph
H
OH Ph COOH

COOH COOH

HO H HO H
Fischer
Me H Me H
Projection
Ph Ph
Chapter 5
 Cl H H Cl
H Cl Cl H

H3C CH3 H3C CH3
(I) (II)
(2S, 3S)-Dichlorobutane (2R, 3R)-Dichlorobutane

CH3 CH3

H Cl Cl H

Cl H enantiomers H Cl

CH3 CH3

 (I) and (II) are both chiral and they are
enantiomers of each other
Chapter 5
 CH3
H H
Cl Cl H Cl

H Cl
H3 C CH3
(III) CH3
(2S, 3R)-Dichlorobutane Plane of
symmetry
 (III) is achiral (a meso compound)
 (III) and (I) are diastereomers of each
other
Chapter 5
14. Stereoisomerism of Cyclic
Compounds
a meso compound
mirror
achiral
H Me H Me Me Me

Me H Me H H H

enantiomers Plane of
symmetry
Chapter 5
 14A. Cyclohexane Derivatives
 1,4-Dimethylcyclohexane

Plane of Both cis- & trans-
Me
symmetry Me 1,4-dimethylcyclo-
hexanes are
achiral and
Me Me
optically inactive
Me H The cis & trans
Me H Me Me forms are

H H diastereomers
cis-1,4-dimethyl trans-1,4-dimethyl
cyclohexane cyclohexane
Chapter 5
 1,3-Dimethylcyclohexane
Plane of
symmetry

Me Me Me
* *
cis-1,3-dimethyl Me
H
cyclohexane H
(meso)
cis-1,3-Dimethylcyclohexane has a
plane of symmetry and is a meso
compound
Chapter 5
 1,3-Dimethylcyclohexane

NO plane of symmetry

Me Me Me Me
* * H H
H H
Me Me
trans-1,3-dimethyl
cyclohexane enantiomers

trans-1,3-Dimethylcyclohexane
exists as a pair of enantiomers
Chapter 5
 1,3-Dimethylcyclohexane
Has two chirality centers but only
three stereoisomers
cis-1,3-dimethyl trans-1,3-dimethyl
cyclohexane cyclohexane

Me Me Me
Me H H
H H H
H Me Me

(meso) enantiomers
Chapter 5
 1,2-Dimethylcyclohexane
mirror
H H
Me Me
Me Me
H H

enantiomers

trans-1,2-Dimethylcyclohexane
exists as a pair of enantiomers
Chapter 5
 1,2-Dimethylcyclohexane
With cis-1,2-dimethylcyclohexane
the situation is quite complicated
mirror
Me Me
H H
Me Me
(I) H H (II)

(I) and (II) are enantiomers to each
other
Chapter 5
 However, (II) can rapidly be
interconverted to (III) by a ring flip
Me Me
2'
H H 2
1' Me Me 1

(I) H H (II)

Me
Me 2
1
H
H (III)
Chapter 5
 Rotation of (III) along the vertical
axis gives (I)
Me Me
2'
H H 2
1' Me Me 1

(I) H H (II)

C1 of (II) and (III)
become C2’ of (I) & Me
C2 of (II) and (III) 2 1 (III)
Me
become C1’ of (I) H
H
Chapter 5
 Me Me
2'
H H 2
1' Me Me 1

(I) H H (II)

Although (I) and (II)
are enantiomers to Me
2 1 (III)
each other, they can Me
H
interconvert rapidly H
 (I) and (II) are
achiral
Chapter 5
15. Relating Configurations through
Reactions in Which No Bonds to
the Chirality Center Are Broken
 A reaction is said to proceed with
retention of configuration at a
chirality center if no bonds to the chirality
center are broken. This is true even if the
R,S designation for the chirality center
changes because the relative priorities of
groups around it changes as a result of
the reaction
Chapter 5
 Same configuration

O OH
NaBH4 H
H MeOH H
Me H Me H

Me H NaCN Me H
Ph Br DMSO Ph CN

Same configuration
Chapter 5
15A. Relative & Absolute Configurations
 Chirality centers in different molecules have
the same relative configuration if they
share three groups in common and if these
groups with the central carbon can be
superimposed in a pyramidal arrangement

Chapter 5
 The absolute configuration of a chirality
center is its (R) or (S) designation, which
can only be specified by knowledge of the
actual arrangement of groups in space at
the chirality center
(R)-2-Butanol (S)-2-Butanol

HO H H OH

enantiomers
Chapter 5
16. Separation of Enantiomers:
Resolution
 Resolution – separation of two enantiomers
O O
OH OMe OMe
e.g. O O
C F3 + C F3
R * R' O Ph Ph
(racemic) R R' R R'
OMe
Cl (1 : 1)
Ph CF3
(Mosher acid diastereomers
chloride) usually separable
either by flash column
chromatography or
recrystallization etc.
Chapter 5
 Kinetic Resolution
OH OH OH
R1 R1 R1
R * R * + R *
R2 R2 O R2
(racemic)

One enantiomer reacts “fast” and
another enantiomer reacts “slow”

Chapter 5
 e.g.
Me3Si t i Me3Si Me3Si
BuOOH, Ti(O Pr)4
O
OH (-)-DET OH + OH
*
C5H11 HO COOEt C5H11 C5H11
(racemic) (-)-DET:
HO COOEt 42% 43%
(D)-(-)-Diethyl Tartrate (99%ee) (99%ee)
 
Me3Si Me3Si

R' S OH H R OH

H R'

* stop reaction at  50%
* maximum yield = 50%
Chapter 5
17. Compounds with Chirality
Centers Other than Carbon

R4 R3 H R3
Si Ge
R1 R2 R1 R2

R4 R3 R2 R1
N X S
R1 R2 O

Chapter 5
18. Chiral Molecules That Do Not
Possess a Chirality Center

Chapter 5
 mirror

H H
H H
C C C C C C
Cl Cl
Cl Cl

enantiomers

Chapter 5
 END OF CHAPTER 5 

Chapter 5