Chemical Kinetics Lecture Notes PDF

Summary

These lecture notes cover chemical kinetics, focusing on topics relevant to pharmaceutical stability, including reaction rates, zero and first-order reactions, pseudo-order reactions, and stability testing. The document outlines common drug degradation reactions and factors affecting them.

Full Transcript

TOPIC 10:
Chemical Kinetics
Learning Objectives
Apply reaction rate and reaction order calculations to drug stability

Discuss the concept of pseudo reaction order

Calculate the half life and shelf life of pharmaceutical products

Discuss stability testing protocols and regulatory requirements

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Outline
1. Common Drug Degradation Reactions
1. Hydrolysis
2. Oxidation
2. Order of Reaction
1. Zero-Order Reactions
2. First-Order Reactions
3. Pseudo Reaction Order
3. Stability and Shelf Life of Drugs
1. Factors
2. Accelerated Stability Testing
3. Enzyme Catalysis Reactions
4. Pharmacokinetics
1. Zero-Order Absorption
2. Frist-Order Absorption
5. Radioactivity 3
Common Drug Degradation Reactions
Most common mechanism of drug degradation (for small molecular pharmaceuticals):

1. Solvolysis (Hydrolysis)
2. Oxidation
3. Photolysis

Focus on solvolysis and oxidation
Since water is the most common solvent encountered by pharmaceuticals, hydrolysis is the
primary solvolysis reaction

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Relevant Terms
CHEMICAL KINETICS
Deals with the stability of drugs and the mode of action of their degradation through the
examination of rates of reaction and reaction mechanisms

STABILITY
The ability of a drug to retain its chemical, physical, microbiological and biopharmaceutical
properties within specified limits throughout its shelf-life

STABILITY TESTS
Series of tests designed to obtain information on the stability of a pharmaceutical product in
order to define its shelf-life and utilization period under specified packaging and storage
conditions

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Relevant Terms
SHELF LIFE
Expiration Dating Period or Validity Period
The period of time during which a drug product is expected, if stored correctly, to remain
within specification as determined by stability studies on a number of batches of the product
Shelf-life is used to establish the expiry date of each batch of drug product
Time required for 10% of the material to disappear, time at which A has decreased to 90% of
its original concentration

EXPIRATION DATE
Date placed on the container label of a drug product designating the time prior to which a
batch of the product is expected to remain within the approved shelf-life specification if
stored under defined conditions and after which is must not be used

HALF LIFE
Time required for one-half of the material to disappear, time at which A has decreased to
1/2A

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Stability Testing
To provide evidence on how the quality of drug substance or drug product varies with time
under the influence of a variety of environmental factors, such as temperature, humidity and
light

To establish a retest period for the drug substance or a shelf life for the drug product and
recommend storage conditions

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Common Drug Degradation Reactions
Most common mechanism of drug degradation (for small molecular pharmaceuticals):
1. Solvolysis (Hydrolysis)
2. Oxidation
3. Photolysis

Focus on solvolysis and oxidation
Since water is the most common solvent encountered by pharmaceuticals, hydrolysis is the
primary solvolysis reaction

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Hydrolysis
Occurs when a water molecule, with the hydroxyl ion (OH-) acting as a nucleophile, interacts
with a functional group to degrade the rug

Major target: carbonyl functional groups (C=O), ex. carboxylic acids, esters, amides

Responsible for the distinctive, vinegary odor of acetic acid in bottles of aspirin stored for
long periods of time under nonideal conditions (high temperature, high humidity)

Can be accelerated by either acids or basis: pH of the aqueous environment is a critical
factor in stability

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Oxidation
While oxygen is not required for an oxidation reaction, oxygen is the primary oxidizing agent
of concern for most pharmaceutical degradation reactions

limiting oxygen by packing product in an inert atmosphere
sealing the bottle with foil to exclude atmospheric exposure prior to dispensing
oxidation reactions may be dependent to pH, the control of pH via buffering may aid in the
inhibition of such degradation reactions
use of chelating agents and antioxidants

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Review of Concepts
Reaction Rates

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Review of Concepts
Reaction Rates

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Review of Concepts
Reaction Rates
Consider the decomposition of N2O5 to give NO2 and O2:

2N2O5 (g) 🡪 4NO2 (g) + O2 (g)

Time (s) [N2O5] [NO2] [O2]
0 0.0200 0 0
100 0.0169 0.0063 0.0016
200 0.0142 0.0115 0.0029
300 0.0120 0.0160 0.0040
400 0.0101 0.0197 0.0049
500 0.0086 0.0229 0.0057
600 0.0072 0.0256 0.0064
700 0.0061 0.0278 0.0070

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Review of Concepts
Reaction Rates
2N2O5 (g) 🡪 4NO2 (g) + O2 (g)

Time (s) [N2O5] [NO2] [O2]
300 0.0120 0.0160 0.0040
400 0.0101 0.0197 0.0049

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Review of Concepts
Reaction Rate and Stoichiometry

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Review of Concepts
Rate Law and Reaction Order

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Review of Concepts
Rate Law, Reaction Order and Rate Constant
Rate Law Order Units of k
Rate = k Zero concentration/time
Rate = k[A] First order with respect to A 1/time
First order overall
Rate = k[A]2 Second order with respect to A 1/concentration x time
Second order overall
Rate = k[A][B] First order with respect to A 1/concentration x time
First order with respect to B
Second order overall

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Order of Reactions
Understanding the rate of reaction, reaction order, and how rate constants are determined will
assist the pharmacist in determining beyond use dates, maintaining proper storage conditions,
and developing stable products.

An effective approach to achieving this understanding is via the mathematical analysis of the
degradation process.

Mass degradation reaction can be illustrated as follows

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Order of Reactions

D drug molecule undergoing degradation
W reacting molecule of water*

d[D] is a very small change in the drug concentration, [D], over a very small change in time,
dt

(-): drug concentration is decreasing with respect to time

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Order of Reactions

k2 : rate constant, represent the speed of the degradation process

What is the reaction order of this equation?

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Order of Reactions

In this generic example, the reaction order is determined to be second order.

Rate constants, k, from different drug degradation reactions of the same reaction order can
be compared to assess the relative stability of drug.

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Order of Reactions
Zero Order Reactions

Rate is independent of the concentrations of the reactants
Rate is determined by a decrease in the drug concentration [D]
Velocity of the decrease in concentration is constant

[D]0 initial drug concentration
[D]t drug concentration after a specified time, t

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Order of Reactions
Zero Order Reactions

Slope is equal to –k0

k0

[D] concentration
[t] time
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Order of Reactions
Zero Order Reactions
HALF - LIFE

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Order of Reactions
Zero Order Reactions
HALF - LIFE

In a zero-order reaction, at ambient temperature, k0 was determined to be
0.380 (mg/mL∙days-1). If the initial drug concentration, [D]0 was 200 mg/mL,
how long will it take for the initial concentration to decrease by 50%?

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Order of Reactions
First Order Reactions

Rate is directly proportional to the concentration of one of the reactants

[D]0 initial drug concentration
[D]t drug concentration after a specified time, t
k first-order degradation constant

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Order of Reactions
First Order Reactions

k0

[D] Concentration
[t] Time
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Order of Reactions
First Order Reactions
HALF - LIFE

[D]t = ½[D]0
t = t1/2

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Order of Reactions

ZERO ORDER FIRST ORDER

Equation for k

Units for k

Equation of t1/2

Equation for t90

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Order of Reactions
Pseudo Reaction Order

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Order of Reactions
Pseudo Reaction Order

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Order of Reactions
Pseudo Reaction Order

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Order of Reactions
Pseudo Reaction Order
A solution of a drug contained 500 units/mL when prepared. It was analyzed after 40 days
and was found to contain 300 units/mL. Assuming the decomposition is first order, at what
time will the drug have decomposed to one-half of its original concentration?

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Stability and Shelf-life of Drugs
SHELF LIFE
Expiration Dating Period or Validity Period
The period of time during which a drug product is expected, if stored correctly, to remain
within specification as determined by stability studies on a number of batches of the product
Shelf-life is used to establish the expiry date of each batch of drug product
Time required for 10% of the material to disappear, time at which A has decreased to 90%
of its original concentration

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Stability and Shelf-life of Drugs
Suppose that for a first order reaction, one had to start with 1.2 mg/mL of drug. To obtain
90% of 1.2, multiply with 0.9

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Stability and Shelf-life of Drugs
Suppose that for a first order reaction, one had to start with 1.2 mg/mL of drug. To obtain
90% of 1.2, multiply with 0.9

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Stability and Shelf-life of Drugs
Suppose that for a first order reaction, one had to start with 1.2 mg/mL of drug. To obtain
90% of 1.2, multiply with 0.9

If k = 0.03 mg/mL/h. Solve for t90.

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Effects of Temperature
Collision Theory of Reaction Rates
The mechanism of a reaction depends on two factors:
1. Frequency factor
2. Activation

The larger the frequency factor, the faster a reaction will procced.
However, not all molecules collide with sufficient energy to contribute to a reaction.
“molecules must have a certain energy to react”

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Effects of Temperature

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Effects of pH
The magnitude of the rate of a reactions catalyzed by H+ and OH- ions can vary considerably
with pH.
The pH of optimum stability can be determined by plotting log k against pH.

When log k increases with a decreasing pH 🡪 acid catalysis

When log k increases with a increasing pH 🡪 basic catalysis

These plots also known as pH-rate profiles, are very useful in guiding the formulation of
stable dosage forms.

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Accelerated Stability Testing

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Accelerated Stability Testing

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Accelerated Stability Testing
It is not practical to wait for years to observe how long it takes for a drug to decompose.
Various types of stress are applied to drug compounds to speed the process.

1. Temperature: accelerate rate of reaction

1. Humidity: increases decomposition by hydrolysis

1. Light: used to increase the effect of daylight or sunlight on a drug product

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Expiration Date Equation
For a first-order reaction, the initial concentration of a drug is 200 mg/mL. The specific rate
constant k is obtained from an Arrhenius plot and is equal to 3 x 10-5 h-1 at 25°C (77°F). The
limit of viability of the drug is 150 mg/mL, at which stage its shelf life has expired.

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Expiration Date Equation
Drug accelerated stability testing, a medicine was analyzed to have 3.2 mg/mL of active drug,
and its stability constant k was found to be 0.05 mg/mL/h. How long will it take before the drug
decomposes by 10%?

[A]t = [A]0 – kt90

END