Lecture 11 - Salt Forms and Solution Formulation Fall 2024 PDF

Summary

This lecture, on pharmaceutical sciences, covers topics such as salt forms, solution formulations, pH calculations and ionic equilibria, emphasizing the drug stability aspects. It's designed to be an informative overview for students interested in this area of study in pharmaceutical sciences.

Full Transcript

Foundations of
Pharmaceutical Sciences
Lecture #11

I. Salt forms
II. Solution formulations

Dr. Lewis Stevens
[email protected]

1
 Overview

Discuss salt forms and their
classification as acidic/basic

Calculation of pH and fraction ionized
for salt forms

One of key issues that ionic equilibria
helps us understand is drug stability
Physical vs. chemical stability

Describe the excipients of solution
formulations and their role,
Buffers, preservative, tonicity, antioxidants,
solvents

2
 Solution formulation

Review questions.

When assessing the strength of two weak acids,
a) the acid with a higher pKA is stronger
b) the acid with a lower pKA is stronger

When assessing the strength of two weak bases,
a) the base with higher pKA is stronger
b) the base with lower pKA is stronger

3
 Solution formulation

Review questions.

When assessing the strength of two weak acids,
a) the acid with a higher pKA is stronger
b) the acid with a lower pKA is stronger

When assessing the strength of two weak bases,
a) the base with higher pKA is stronger
b) the base with lower pKA is stronger

4
 Solution formulation
pKA = 9

Our previous examples, where we
calculated fraction ionized, had only
one ionizable functional group.

For molecules with more than one
ionizable group, we look at each
group and determine % ionized for
each one.

pKA = 4
Generally, except for very large
molecules, if at least one functional If a solution of this drug was buffered
group is ionized, at a given pH, there to pH = 7, the net overall charge on
won’t be a concern of precipitation this molecule is zero. Is this molecule
unionized at pH = 7?

ANS: Net overall charge is zero. At pH = 7, the aliphatic is 100% ionized (has a +
charge) and at pH = 7, the carboxylic acid is 100% ionized (has a – charge).
5
 Solution formulation
Cl-
A very common pharmaceutical form
you’ll often encounter is the salt
form,
Lidocaine HCl
Naproxen Sodium
Ephedrine Sulfate (lidocaine HCl)

Salt forms of a drug compound are
often used to significantly boost their
water solubility

Salts are formed from the reaction of
an acid and a base (naproxen sodium)

Here we’ll look at acid-base reactions
by which typical salts are formed

6
 Solution formulation

There are a variety of ways salt forms
may be indicated on the drug product
insert. Consider atorvastatin calcium.

In this example, the ionized group is shown. A carboxylate carries a
-1 charge, and since the counterion (Ca) has a +2, then there are 2
ionized atorvastatin molecules for every Ca2+.

This indicates the solid form is a hydrate with 3
water molecules for every 2:1 atorvastatin Ca salt

7
 Solution formulation

There are a variety of ways salt forms
may be indicated on the drug product
insert. Another way to represent a
salt is shown for acebutolol HCl.

This does not mean that acebutolol and
HCl are distinct species, but rather the
HCl salt.

What would the actual species look like?

8
 Solution formulation

There are a variety of ways salt forms This is the
may be indicated on the drug product
insert. Another way to represent a
salt is shown for acebutolol HCl.

-

+

This is the only
ionizable group in
acebutolol.

9
 Solution formulation

Salts of acidic drugs can be made by reaction with a
strong base, typically sodium or potassium hydroxide
weakly associated
counterion

+ KOH → H2O +

Penicillin V Potassium Penicillin V

Penicillin V parent molecule is an The salt form looks like the conjugate
acid (due to carboxylic acid group) base of the weak acid free form.

So, if you put this salt form into water,
Salt compound name includes the counter ion, e.g.
would you expect the pH greater or
sodium or potassium, either before or after the
compound name. lower than 7?

10
Solution formulation
weakly associated
counterion

+ KOH → H2O +

Penicillin V Potassium Penicillin V

Penicillin V parent molecule is an The salt form looks like the conjugate
acid (due to carboxylic acid group) base of the weak acid free form.

So, if you put this salt form into water,
would you expect the pH greater or
lower than 7?

ANS: The pH would be above 7. If you put potassium penicillin V (the
conjugate base of Penicillin V) into water, it will act like any other base. You
would use a base pH equation to calculate pH of the solution.
11
 Solution formulation

Another example. Starting material is a weak
acid (see the imide group) that is converted weakly associated
to a salt form by a strong base (NaOH) counterion

Na+ -

+ NaOH → H2O +

Phenytoin Phenytoin Sodium

Parent molecule is an acid Salt is a base. Note again,
(due to imide group) conjugate base of the
weak acid free form.

12
 Solution formulation

Consider a 0.1 M solution of sodium phenytoin, what’s
the pH going to be? (pKA = 8.3) Na+ -

a) 12.40
b) 10.65
c) 3.55
d) 1.00

13
 Solution formulation

Consider a 0.1 M solution of sodium phenytoin, what’s the pH going
to be? (pKA = 8.3)

When we put the salt form of a drug in solution, the first thing that
happens is the salt dissociates. Then we have a base in solution
(specifically the conjugate base of phenytoin)

-
+ H 2O ↔ OH − +

Is the pH of the solution going to above or below 7?
What equation are you going to pick, weak acid or weak base?
14
 Solution formulation

Sodium phenytoin is going to act like a base,
and therefore we select the base pH equation.
Expect a solution of sodium phenytoin to be
higher than 7.

I selected this version of the base pH
equation, but you choose any and you’ll get
the same answer.
[OH − ] = K B Cb
Since pKA = 8.3, then pKB = 5.7 and then, K B = 10 −5.7

And, [OH − ] = K B Cb = 10 −5.7 ⋅ 0.1 = 4.47 × 10 −4

pOH = − log[OH − ] = − log[4.47 × 10 −4 ] = 3.35 and pH = 14 − 3.35 = 10.65

15
 Solution formulation

For the previous example, you could use any equations for a weak
base, and you would arrive at the same answer.

weak base

16
 Solution formulation

Consider a 0.1 M solution of sodium phenytoin, what’s the pH going
to be? (pKA = 8.3)

When we put the salt form of a drug in solution, the first thing that
happens is the salt dissociates. Then we have a base in solution
(specifically the conjugate base of phenytoin)

-
+ H 2O ↔ OH − +

1 1 Another way to
𝑝𝑝𝑝𝑝 = 14 + 𝑝𝑝𝐾𝐾𝐴𝐴 + 𝑙𝑙𝑙𝑙𝑙𝑙 𝐶𝐶𝑏𝑏 = 14 + 8.3 + 𝑙𝑙𝑙𝑙𝑙𝑙𝑙.1 = 10.65
2 2 the same answer

17
 Solution formulation

Salts of basic drugs can be made by reaction
with a strong acid, typically hydrochloric,
sulfuric, nitric or perchloric acid.
Cl-
H+
+ HCl →

Procaine Procaine hydrochloride or procaine HCl

Parent molecule is a base. Recognize the salt is the conjugate acid
The pKA for procaine is 8.9. of parent base

When you put procaine HCl in solution is
the pH going to be above or below 7.0?
ANS: The pH would be below 7. If you put procaine HCl (the conjugate acid
of procaine) into water, it will act like any other acid. You would use a acid pH
equation to calculate pH of the solution.
18
 Solution formulation

Question.
What would the pH of a 0.1 M solution of
procaine HCl be?
a) 6.95
b) 4.95
c) 2.95
d) 1.00

19
 Solution formulation

Question. What would the pH of a 0.1 M
solution of procaine HCl be?

First, this species is the conjugate acid of the
procaine free base.

We recognize that we’re dealing with acid, so
we select an acid pH equation. I chose this one [ H 3O + ] = K A C a

pKA = 8.9, so K A = 10 −8.9

Now plug in what we know, [ H 3O ] =
+
K ACa = 10 −8.9 ⋅ 0.1 = 1.12 × 10 −5

And, then pH = − log[ H 3O + ] = − log[1.12 × 10 −5 ] = 4.95

20
 Solution formulation

Concept question.
What would you expect the fraction ionized
be for a salt form?
a) near zero
b) near 100%

21
 Solution formulation

Now, fraction ionized is calculated with From the previous procaine HCl example, we
respect to the free form, i.e. the calculated the pH of the solution to be, pH =
unionized functional group. This is what 4.95.
guides our selection of the acid or base
equations. The pKA for this tertiary amine is given as 8.9.

Continuing with the example for Plugging in what we know,
procaine HCl, the functional group of
interest is the tertiary amine. 8.9−4.95
𝐵𝐵𝐵𝐵 +
10 = 103.95 =
𝐵𝐵
This tertiary amine is a basic functional
group. Thus to calculate the fraction
ionized select the base fraction ionized 103.95
equations: ( pK A − pH ) [ BH + ] %𝑖𝑖𝑖𝑖𝑖𝑖𝑖𝑖𝑖𝑖𝑖𝑖𝑖𝑖 = × 100 ≈ 100%
1 + 103.95
10 =
[ B]
[ BH + ] Do your sanity check, i.e. the
[ BH + ] [ B]
% ionized = +
× 100 = × 100 pH is 2 units below the pKA
[ B ] + [ BH ] [ BH + ]
1+ for a basic functional group.
[ B]
22
 Solution formulation

As we’ve seen already, many drugs have poor
water solubility and some of those drugs lack
an ionizable functional group
Digoxin, shown to the right

To accommodate this for a solution
formulation, e.g. injection, co-solvents are
needed
Alcohol
Propylene glycol

These inactive ingredients (excipients) are vital
Remember, a drug product
components to a preparing a safe and
effective formulation typically contains more than
Stability of the drug product is a primary concern just the drug. Excipients are a
While our current emphasis is solution formulations; vital component to ensuring
however, this true for all types of dosage forms drug product quality.

23
 Solution formulation

Our definition of stability is as follows:
Absence of unacceptable changes in the
performance properties of a pharmaceutical
product in the presence of environmental A primary oversight body to
stress associated with manufacturing, the pharmaceutical industry to
shipping, storage and use. ensure product quality is
adequately documented and
The two primary classifications of stability verified.
are:
Physical – non-covalent changes to the
product components
For physical instability, the molecules remain
the same.
Chemical – changes to covalent bonding Both mechanisms of instability can
be sensitive to changes in pH.
of the product components
For chemical instability, the molecules are
changed, so you’re no longer dealing with the
SAME molecule.

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 Solution formulation
In a solid form, the molecules have a
specific arrangement in space.
Physical instability may arise through
multiple ways, e.g.:
Changes in structure (not at the molecular
level but the solid phase level)
This is known, as polymorphism.
Changes in phase (soluble components →
insoluble solids)
Non-covalent interactions between drug and
excipients/co-solvents
Remember, changing the spatial
Non-covalent interactions between drug and arrangement of the same molecule
packaging components
yields a different polymorph, and this
Physical instability can manifest as, e.g.: impacts the physical properties of
Precipitation* (change in pH may change the solid drug: dissolution,
drug solubility leading to precipitation) compaction, kinetics, bioavailability,
etc.
Aggregation (particularly problematic for
biopharmaceuticals)
Changes in pH particularly when
Complexation administering two drugs through single
Phase transformation IV line can lead to incompatibility.

25
 Solution formulation

Apart from the example of IV compatibility,
changes in physical stability can
subsequently result in,

Dissolution failure – If the drug dissolves at
different rate, it’s bioavailability is going to
change. (Remember, the ritonavir example)

Mechanical failure – tablets lose their
integrity, break apart = poor dose consistency

Sedimentation – Precipitation (drug comes
out of solution)

Partitioning – Phase separation (same idea as
sedimentation, but generally for liquids)

Loss of potency
26
 Solution formulation

Excipients are introduced into the formulation
to improve efficacy and product stability

Classes of excipients include, e.g.
Solvent and co-solvent, preservatives, antioxidants,
buffers

Typical pharmaceutical solvents,
Water
Alcohols These are miscible with water and
Alcohol USP, 94.9 – 96.0% v/v of C2H5OH typically used to solubilize poorly
Glycols water-soluble compounds.
Glycerin
There are limits with how high the
alcohol % (v/v) can be in an orally
Propylene glycol
ingested preparation, so need to
calculate what minimum quantity
would suffice.
Oils

27
 Solution formulation

Buffers are another
important excipient in
solution formulation.

Buffers are designed to
maintain the solution at a
constant pH (we’ll discuss
more about these later)

Common pharmaceutical
buffers are shown to the
right.

Acidifying and alkalizing
agents are used for pH
adjustment (up, alkalizing)
and (down, acidifying)

28
 Solution formulation

pH is important to dosage design to ensure
adequate solubility so the formulation
remains a stable product for
administration.

rate of degradation
Mixing solutions of significantly different pH and
lead to physical instability (precipitation of the
drug)

Shown to the right is a pH rate profile.
Those regions circled designate the best
formulation pH with respect to chemical
stability.

Often the pH of a solution formulation is
selected to (1) maintain solubility and (2)
minimize potential chemical degradation. Increasing [H+]
Degradation is a bigger concern for solutions than
for solids, i.e. tablets. Increasing [OH-]

29
 Solution formulation

Preservatives – added
to nonsterile dosage
forms to inhibit
microbial growth

Propylene glycol (in
most formulations)
effective at 10% w/v

At solution pH less
than pH = 3 or greater
than pH = 9, then
preservatives aren’t
generally needed

30
 Solution formulation

Oxidation is another primary
degradation mechanism, generally
follows an auto-oxidation process.
Initiation In: Initiator (could be drug,
Propagation excipient or trace metal)
Termination

An initiating event (not O2 acting directly
on the drug) generates a drug radical (H-abstraction)
(unpaired electron) that is very reactive. drug
Metal ion, light, heat

Radical species propagate the reaction
further generating more radical species.

Termination step occurs when two
radical species join to together to form a
non-radical chemical bond.

31
 Solution formulation

Chelating agents and antioxidants are
included to help reduce potential of
oxidative degradation.

Chelating agent – complexes with
ions metal ions, e.g.
Edetate calcium disodium
Edetate disodium
EDTA – ethylenediaminetetraacetic acid

Antioxidants –
easily oxidized, e.g. sulfite family, act as
scavengers to protect the drug from
oxidation
Reducing agent, e.g. Na thiosulfate, act to
reduce an oxidized species

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 Summary

Salt forms of drugs are routinely used to Na+
boost water solubility
We can treat these forms in a similar way as
seen in Lecture 1.

It’s important to recognize the drug
product is more than just the drug
Solvent system
Preservatives
Buffers
Antioxidants
All deliberately chosen to ensure an effective
and safe drug product

Combining drug products without paying
attention to solvent system, buffer, or
excipients has the potential for physical
and chemical instabilities

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