Pharmaceutical Organic Chemistry I PC101 Lecture Notes PDF

Summary

This document is a set of lecture notes on Pharmaceutical Organic Chemistry I PC101. It covers introduction for organic chemistry, learning outcomes and includes various concepts such as classes of organic chemical reactions, hybridization, intermolecular forces, and chemical reactions. The notes contain examples and questions, making it a valuable resource for undergraduate students.

Full Transcript

Pharmaceutical Organic Chemistry I PC101

Introduction for Organic Chemistry

Mona S. El-Zoghbi, Ph. D. Pharm. Sc.
Associate professor of pharmaceutical Chemistry
Pharmaceutical Chemistry Department
[email protected]
Intended learning outcomes of the course (ILOs)
On successful completion of the course, you should be able to:

❖Recognize several organic terms.

❖Underline the different types of chemical bonds.

❖Recognize the different classes of organic compounds.

❖Assess the structural feature of organic compound and its IUPAC name.

❖Demonstrate alkanes, alkenes, alkynes and alkyl halides (nomenclature, physical and chemical
properties, preparation and chemical reactions).

❖ Classify different reaction mechanism.

❖ Outline fundamental principles and applications of stereochemistry, stereo-dynamic, hydroxyl and
carbonyl compounds.
❖ Identify the principles of aromaticity and benzenoid compounds.
1. Which of the following rules states that “In the ground state of an atom or ion, electrons fill subshells of the
lowest available energy, then they fill subshells of higher energy”?
a. Octet rule b. Aufbau Rule
c. Pauli Exclusion rule d. Hunds Rule

2. Which of the following is monovalent atom?

a. Oxygen b. Nitrogen c. Argon d. Fluorine

3. How many covalent bonds does carbon form?
a. 2 b. 3 c. 4 d. None, it dose not form covalent bond
lone pair
It refers to a pair of valence electrons that are not shared with another atom
and is sometimes called a non-bonding pair. Lone pairs are found in the
outermost electron shell of atoms.

The Shape of Molecules

The three-dimensional shape or configuration of a molecule is an important
characteristic.

Methane Ammonia Water
1. Shape of molecules without lone pair of electron
Bonding Bond
Configuration Example
groups Angles

Tetrahedral 4 109.5º

Trigonal 3 120º

Linear 2 180º
Isomers

Different compounds having the same molecular formula
 Structural Formulas for C 4H10O Isomers (as example)

Kekulé Formula Condensed Formula Structural Formula
Shorthand or line formula
or skeletal formula
Resonance
is a way of describing delocalized of pi electrons within certain molecules or
polyatomic ions where the bonding cannot be expressed by one
single structure.

NB: The double headed arrow being the unique symbol for resonance.
There are different groups of carbon atoms:
A primary carbon (1º)
is one that is bonded to no more than one other carbon atom.
A secondary carbon (2º)
is bonded to two other carbon atoms.
Tertiary (3º) and quaternary (4º) carbon atoms

are bonded respectively to three and four other carbons.
Ex. What is the total number of tertiary carbons found in the following compound?
Intermolecular Forces
All atoms and molecules have a weak attraction for one another, known as
van der Waals attraction forces.

If there were no van der Waals forces, all matter would exist in a
gaseous state.
1.Dipole–dipole attraction force.
attractive forces between the positive end of one polar molecule and the
negative end of another polar molecule.
2. Hydrogen Bond
Electrostatic attraction between a hydrogen (H)
which is bound to a more electronegative atom such
as nitrogen (N), oxygen (O), or fluorine (F), and
another adjacent atom bearing a lone pair of
electrons.
The hydrogen bond is weaker than an ordinary
covalent bond but is much stronger than the
dipole–dipole interactions.
 Hydrogen bonding accounts for the fact that ethyl alcohol has a much
higher boiling point (78.5°C) than dimethyl ether (24.9°C) even though
the two compounds have the same molecular weight.

✓ Molecules of ethyl alcohol, because they have a hydrogen atom covalently
bonded to an oxygen atom, can form strong hydrogen bonds to each
other.

✓ Molecules of dimethyl ether, because they lack a hydrogen atom attached
to a strongly electronegative atom, cannot form strong hydrogen bonds to
each other.
✓ In dimethyl ether the intermolecular forces are weaker dipole–dipole
interactions only.
Q1. Which among the following compounds cannot form hydrogen bond?
Solubility of organic compounds in Water

Many organic compounds, especially alkanes and other hydrocarbons are
nearly insoluble in water.
Organic compounds that are water soluble, such as ethanol and acetone,
generally have hydrogen bond acceptor and donor groups.
Hydrophilic moiety
polar, hydrogen bonding moieties
Hydrophobic moiety
nonpolar species
Chemical Reaction:
A transformation of the reactants into the reaction products
Reactant
It is the organic compound undergoing change in a chemical reaction.
Product
It is the final result of the chemical reaction
Reaction Conditions
The environmental conditions, such as temperature, pressure, catalysts &
solvent, under which a reaction progresses optimally.
Catalysts
These are substances that accelerate the rate of a chemical reaction without
themselves being consumed.
Classes of Organic Chemical Reactions
1-Classification by Structural Change
Addition, Elimination, Substitution and Rearrangement
Addition: In an addition reaction the number of σ-bonds in the substrate
molecule increases, usually at the expense of one or more π-bonds.
Elimination reactions: the number of σ-bonds in the substrate decreases, and
new π-bonds are often formed.

Substitution: replacement of an atom or group (Y) by another atom or group (Z).
In this reaction, the number of bonds does not change.
A rearrangement reaction generates an isomer, and again the number of bonds
normally does not change.
Exercise:
2-Classification by Reaction Type
Oxidation and Reduction Reactions
If the number of hydrogen atoms bonded to a carbon increases, and/or if
the number of bonds to more electronegative atoms decreases, the carbon
in question has been reduced.
If the number of hydrogen atoms bonded to a carbon decreases, or if the
number of bonds to more electronegative atoms increases, the carbon in
question has been oxidized.
Reduced= blue Oxidized= red
 3-Classification by Functional Group
Functional Class Formula Characteristic Reactions
Substitution (of H, commonly by Cl or Br)
Alkanes C–C, C–H
Combustion (conversion to CO2 & H2O)
Addition
Alkenes C=C–C–H
Substitution (of H)
Addition
Alkynes C≡C–H
Substitution (of H)
Substitution (of X)
Alkyl Halides H–C–C–X
Elimination (of HX)

Substitution (of H); Substitution (of OH)
Alcohols H–C–C–O–H
Elimination (of HOH); Oxidation (elimination of 2H)

Ethers (α)C–O–R Substitution (of OR); Substitution (of α–H)
Substitution (of H);
Amines C–NRH
Addition (to N); Oxidation (of N)
Benzene Ring C6H6 Substitution (of H)
Addition
Aldehydes (α)C–CH=O
Substitution (of H or α–H)
Addition
Ketones (α)C–CR=O
Substitution (of α–H)
Substitution (of H); Substitution (of OH)
Carboxylic Acids (α)C–CO2H
Substitution (of α–H); Addition (to C=O)
(α)C–CZ=O Substitution (of Z); Substitution (of α–H)
Carboxylic Derivatives
(Z = OR, Cl, NHR, etc.) Addition (to C=O)
Factors that Influence Reactions
1. Type of chemical bond:
Compounds constructed of strong covalent bonds are more stable than
compounds incorporating one or more relatively weak bonds.
2. Electronic Effects:
The distribution of electrons at sites of reaction (functional groups) is a
particularly important factor.
An inductive effect A resonance effect
3. Steric Effects:
Atoms occupy space. When they are crowded together, van der Waals
repulsions produce an unfavorable steric hindrance.
Ex. The steric effect of tri-(tert-
butyl)amine makes electrophilic reactions, like
forming the tetraalkylammonium cation, difficult. It
is difficult for electrophiles to get close enough to
allow attack by the lone pair of the nitrogen
(nitrogen is shown in blue)

4. Solvent Effects:
Most reactions are conducted in solution, not in a gaseous state.
The solvent selected for a given reaction may exert a strong influence on its
course.
 Mechanisms of Organic Reactions
Reaction mechanism
A detailed description of the changes in structure and bonding that take place
in the course of a reaction

Chemical reactions involve the breaking and making of bonds
In general, two kinds of curved arrows are used in drawing mechanisms:

A full head arrow indicates complete
movement or shift of an electron pair:

A half headed arrow indicates the shift of
a single electron:
Homolysis
If a covalent single bond is broken so that one electron of the shared pair
remains with each fragment
Heterolysis
If the bond breaks with both electrons of the shared pair remaining with
one fragment
 In representing reaction mechanism, curved arrows must start from an
electron rich species which may be a negative charge, a lone pair, or a
bond.
Arrowheads must direct towards an electron deficient species which may be
positive charge, the positive end of polarized bond

The Reaction Arrow The Equilibrium Arrow The Resonance Arrow
Reaction Arrow 2 H2 + O2 2 H2O + Energy

O O

OH + H2O O + H3O
Equilibrium Arrow
H3C H3C

H H
Resonance Arrow C O C O
H H
Reactive Intermediates (Transient The products of bond breaking
are not stable and cannot be
intermediates) isolated for prolonged study
Electrophiles
An electron deficient atom or molecule that has an affinity for an electron pair,
and will bond to a base or nucleophile. E.g. RCHO
Nucleophiles
An atom or molecule that has an electron pair that may be donated in bonding
to an electrophile. E.g. R-NH2, R-O-H
Electron deficient groups are attracted to electron rich groups.

Carbocations are electrophiles

Carbanions are nucleophiles
 Carbenes have only a valence shell sextet of electrons and are therefore
electron deficient so, it considered electrophiles.

Carbon radicals (free radicals) have only seven valence electrons, and
may be considered electron deficient; however, they do not in general
bond to nucleophilic electron pairs, so their chemistry exhibits unique
differences from that of conventional electrophiles.
Examples for electrophiles and nucleophile

Ex. Which of the following is an electrophile?
A. CH3CH3
B. CH3CH2+
C. CH3CH2.
D. H2O
 Hybridization in organic compounds
Hybridization is the term applied to the mixing electrons of
atomic unequivalent orbitals in an atom to generate a set of new
equivalent hybrid orbitals.
1.SP3 hybridization (CH4)
 Mixing of the electron in 2S with the three electrons of 2P
produced 4 SP3 hybrid orbitals available to make 4 sigma bonds

form four sigma bonds with 4 hydrogen
atoms through head to head overlapping

have the tetrahedral shape.
2. SP2 hybridization (C2H4)
 Ethylene molecule contains a C=C and has planner geometry

Only 2Px and 2Py orbitals combine with the 2S orbital while the 2Pz orbital
remains unchanged and appears perpendicular to the plane of the 3 hybrid
orbitals
Each carbon atom use the 3 SP2 hybrid orbitals to
form 2 bonds with 2 Hydrogen atoms and the last
orbital of SP2 type to form bond with the adjacent
carbon by head to head overlapping

The 2 unhybridized Pz orbitals form double
bond (π bond) by sideway overlapping
3. SP hybridization (C2H2)
 Acetylene molecule has a linear geometry, contains a carbon carbon triple
bond
hybridization take place between the remaining electron in 2S orbital and
the electron in 2Px to produce 2 hybrid orbital of SP type. 2Py and 2Pz
orbitals remains unhybidized.
The 2 Sp hybrid orbitals of each carbon form sigma bond with one hydrogen
atom and sigma bond with the adjacent carbon by head to head
overlapping. An additional two bi bonds formed by the sideway overlapping
between the two 2Py and 2PZ unhybridized orbitals of each carbon.
Which of the following line structures match the below condensed structural formula?

(CH3)3CCH2CH(CH3)C2H5
1. Differntiate between ionic and covalent bond

2. Draw the electronic configuration of fluorine atom (its atomic No.=9)

3. What type of chemical bonding will be found in magnesium oxide?
4. Which of the following is an electrophile?

a) CH4 CH + c) OH- d) H
b) 3 2O

5. ………………. is a trivalent atom (valence of this atom is 3).

a) Carbon b) Nitrogen c) Oxygen d)Fluorine

6. Mark the hydrogen bond donor?
 Which of the following reactions is an addition reaction?

Which of the following line structures match the below condensed structural formula?

(CH3)3CCH2CH(CH3)C2H5
 What is the total number of tertiary carbons found in the following compound?

Which among the following compounds cannot form hydrogen bond?

A compound having a bond angle 180° is……………………

A. Alkyne
B. Alkene
C. Alkane
D. Cycloalkane
 Which of the following structures is incorrect?

How many covalent bonds does carbon form?

A. 2
B. 3
C. 4
D. None, it dose not form covalent bond

The following reaction is ………………..
 Determine the aldehydic species

Alkanes react mainly through?

a) Addition
b) Elimination
c) Substitution
d) Rearrangement

Which structural formula is not an isomer of the molecular formula C5H10O?