Topical Agents PDF

Summary

This document provides an overview of topical agents, categorizing them based on their intended action (protective, antimicrobial, and astringent). It particularly focuses on the properties and applications of various topical agents such as talc, zinc oxide, and calamine.

Full Transcript

Inorganic Pharmaceutical Chemistry: Topical Agents

This chapter discusses the use of topical compounds, which are applied to body
surfaces, in contrast to systemic compounds that are absorbed into the bloodstream.
Topical drugs primarily act at the surface of application, but in some cases, they
may penetrate deeper tissues, leading to both beneficial and potentially harmful
systemic effects, such as toxicity or allergic reactions. Some drugs, like antiseptics,
can prevent deep infections by penetrating wound tissues, while others (e.g.,
mercury-based compounds) can be toxic if absorbed in large amounts.

Topical compounds are categorized based on their action: (1) protective agents (2)
antimicrobial and (3) astringent compounds.

Protective Agents

Protectives are substances which may be applied to the skin to protect certain areas
from irritation, usually of mechanical origin. Those compounds or substances most
appropriate for this purpose are insoluble and chemically inert. Insolubility is a
desirable property in that this limits the absorption of the compounds through the
skin, makes it difficult to wash them off, and diminishes metallic properties on
tissue. Compounds which are chemically unreactive are necessary to prevent
interactions between the protective substance and the tissue. In other words, ideal
protectives are biologically inactive.

Many protectives also act as adsorbents, efficiently absorbing moisture from the
skin’s surface, which reduces mechanical friction and irritation. The effectiveness
of these substances improves with smaller particle size, as finer particles offer a
larger surface area for adhesion and better moisture absorption. These protectives
are commonly used as powders, ointments, or suspensions, and may also help
soothe irritated skin.

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Inorganic Pharmaceutical Chemistry: Topical Agents

1- Talc (3MgO 4SiO₂ H₂O)

Talc is a native, hydrous magnesium silicate, sometimes containing a small
proportion of aluminum silicate. The U.S.P. describes it as a very fine, white or
grayish white, crystalline powder. It is unctuous, adheres readily to the skin, and is
free from grittiness. Talc is a layered silicate and is the softest mineral known. It
has a smooth, greasy feeling to the touch, and in its lump form (steatite) it is
known as soapstone. Talc is odorless, tasteless, and insoluble in water, dilute acids,
and dilute bases. It has very low adsorptive properties. A hydrothermal method can
be used to mimic the natural geological conditions under which talc forms. The
reaction typically involves reacting magnesium oxide or a magnesium salt with
silica in an aqueous solution at elevated temperatures and pressures.

MgO + H₂O → Mg(OH)₂

3Mg(OH)₂ + 4SiO₂ → Mg₃Si₄O₁₀(OH)₂ + H₂O

Chemically, talc may consider to be a hydrated magnesium silicate having the
elements illustrated by the formula represented above. The actual composition of
talc is somewhat variable, containing from 28.1 to 31.2% MgO, 57 to 61.7% SiO ₂,
and 3 to 7% H₂O. As a magnesium polysilicate, it is unreactive to acids and bases,
and inert to most other reagents.

Talc can be used as:

 lubricating, protective dusting powder. It can be used to prevent irritation
due to friction, and to protect areas from further irritation.
 Talc is used in preparations which may be perfumed for cosmetic purposes,
or medicated with antimicrobial agents, such as boric acid.

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Inorganic Pharmaceutical Chemistry: Topical Agents

2- Zinc Oxide (ZnO; Mol. Wt. 81.37)

Zinc Oxide is a very fine, odorless, amorphous, white or yellowish white powder,
free from gritty particles. It gradually absorbs carbon dioxide from the air. When
heated to 400° or 500°C, the oxide develops a yellow color that disappears on
cooling. Zinc Oxide is insoluble in water and alcohol and will gradually absorb
carbon dioxide from the air to form a basic zinc carbonate [Zn₂(OH)₂CO₃].

Chemically, zinc oxide reacts with dilute acids and aqueous solutions of
ammonium compounds to form water-soluble products. When treated with dilute
hydrochloric acid, the oxide forms the Lewis acid, zinc chloride.

ZnO + 2HCl → ZnCl₂ + H₂O

Zinc oxide can be used as:

 Mild astringent and a weak antimicrobial compound. The antimicrobial-
astringent action is due to the release of a small amount of zinc ion from
hydrolysis in the acidic moisture on the skin
 Astringent and topical protective in ointments in the treatment of skin
ulcerations and other dermatological problems.
 Zinc oxide is the primary ingredient in Calamine.

3- Calamine (ZnO Fe₂O₃)

Calamine is zinc oxide with a small proportion of ferric oxide. The presence of the
ferric oxide (Fe₂O₃) gives the substance a pink color. The material is a fine
powder, odorless, and practically tasteless. It is insoluble in water, but almost
completely soluble in mineral acids.

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Inorganic Pharmaceutical Chemistry: Topical Agents

The term calamine, besides being applied to the official product, is also used to
describe the impure, naturally occurring zinc carbonate. The official Calamine is
obtained by calcination (powdered by heating) of the natural ore. The calcined
product is then passed through a 100-mesh sieve to obtain the finely powdered
material necessary for good cohesive and adhesive (adhering to skin) properties.

 Thermal Decomposition of Zinc Carbonate:
ZnCO₃ → heat ZnO + CO₂
 Calamine Formation:
ZnO + Fe₂O₃ → ZnO⋅xFe₂O₃ (Calamine)

Calamine is a topical protective. It is used in dusting powders, ointments, and
lotions (Calamine Lotion, U.S.P.) where it is applied to the skin for its soothing,
adsorbent, protective properties.

Antimicrobial Agents
These are the chemicals, and their preparations used for the prevention and/or
reduction of infection caused by microorganisms. The terminology of
antimicrobial agents include:

 Antiseptic: A substance that kills or inhibits the growth of microorganisms,
usually applied to living tissues (e.g., skin) to prevent infection.
 Germicide: A substance that kills microorganisms outright. This term
includes agents like bactericides (kills bacteria), fungicides (kills fungi), and
amebicides (kills protozoa).
 -stat (e.g., bacteriostat): Refers to agents that do not kill microorganisms but
inhibit their growth. For example, a bacteriostat stops bacteria from
multiplying.

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Inorganic Pharmaceutical Chemistry: Topical Agents

 Disinfectant: A chemical used to kill microorganisms on inanimate objects,
such as instruments or surfaces, but not safe for use on living tissue.
 Sterilization: A process (often using heat or chemicals) that completely
removes or kills all microorganisms from an object, making it free of any
life.

The mechanisms of action of inorganic antimicrobial agents can be divided into
three general categories: oxidation, halogenation, and protein precipitation.

I- Oxidation: those compounds are generally nonmetals and certain types of
anions. Most common among these are hydrogen peroxide, metal peroxides,
permanganates, halogens (i.e., chlorine and iodine), and certain oxo-halogen
anions. The effective oxidative action of these compounds involves the reducing
groups present in most proteins, e.g., the sulfhydryl (-SH) group in cysteine. An
illustration of the reaction between the oxidizing antiseptic and a sulfhydryl-
containing protein is shown in Fig1. Based on the concept that the protein has a
specific function in the microorganism, e.g., enzyme, the formation of the disulfide
bridge (Fig1-B) will alter the conformation (shape) of the protein and thereby alter
its function.

II- Halogenation: This is a reaction occurring with antiseptics of the hypohalite
type and hypochlorite, OCl⁻. It is expected that a similar reaction can take place

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Inorganic Pharmaceutical Chemistry: Topical Agents

under appropriate conditions with the peptide linkage between the amino acid
groups comprising the protein molecule.

This reaction is ultimately destructive to the function of specific proteins because
the substitution of the chlorine atom for the hydrogen produces changes in the
forces (hydrogen bonding) responsible for the proper conformation of the protein
molecule.

III- Protein Precipitation: This type of mechanism involves the interaction of
proteins with metallic ions having large charge/radius ratios or strong electrostatic
fields. This property is available in transition metal cations, e.g., Cu(II), Ag(I), and
Zn(II). Aluminum(III), due to its charge and small ionic radius, is also an effective
protein precipitant.

The nature of the interaction is one of complexation in which the various polar
groups on the protein act as ligands (see Fig2). The complexation of the metal
results in a radical change in the properties of the protein or protein precipitant.
The interaction of metal ions with protein is nonspecific, and at sufficient
concentration will react with host as well as microbial protein. The presence of the
metal "ties up" important functional groups at the active site on the enzyme.

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Inorganic Pharmaceutical Chemistry: Topical Agents

1- Hydrogen Peroxide Solution (H₂O₂; Mol. Wt. 34.02)

Hydrogen Peroxide Solution is a clear, colorless liquid which may be odorless or
may have an odor resembling that of ozone. The solution will usually deteriorate
upon standing or upon agitation, and rapidly decomposes when in contact with
many oxidizing or reducing substances. It is unstable on prolonged exposure to
light and may decompose suddenly when rapidly heated.

Chemically, hydrogen peroxide may be stable in solutions of high purity; however,
small amounts of contaminants, e.g., divalent and polyvalent ions of chromium,
iron, copper, mercury, etc., will catalyze the decomposition of unstabilized
solutions. Hydrogen peroxide solutions may be stabilized with acids, complexing
agents, or adsorbents.

Depending upon the chemical environment, hydrogen peroxide will react as either
an oxidizing or reducing agent. The oxidation state of oxygen in the peroxide ion,
(O-O)²⁻, is -1. When hydrogen peroxide functions as an oxidizing agent it forms
two oxide ions, O²⁻, requiring two electrons, and resulting in a change of the
oxidation state of the oxygen to -2.

(O2) −2 ⟶ 2O −2 + 2e−

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Inorganic Pharmaceutical Chemistry: Topical Agents

This type of reaction is most efficient in acidic media to produce water

H2O2 + 2H+ + 2e− ⟶ 2H2O

The reducing actions of hydrogen peroxide result in the evolution of molecular
oxygen. This involves the release of two electrons and a change from the peroxide
ion to an oxidation state of zero.

(O2)−2 ⟶ O2 + 2e−

The primary use of Hydrogen Peroxide Solution is:

 As a mild oxidizing antiseptic. This action is produced when the solution
encounters open or abraded tissue, exposing the chemical to the enzyme,
catalase. This enzyme catalyzes the decomposition of H₂O₂ to water and
oxygen.
 When diluted with one part of water, it can be used as a gargle or
mouthwash in the treatment of bacterial infections of the throat and mouth.
 Half-strength solutions may also be used as a vaginal douche.

2- Sodium hypochlorite Solution

It is a clear, pale greenish-yellow liquid having an odor of chlorine. The solution is
affected by light. Common household bleach is usually a 4.5 to 5.0% solution of
sodium hypochlorite.

The Diluted Sodium Hypochlorite Solution is prepared by diluting the original
sodium hypochlorite solution with five times its volume of purified water. The pH
is then adjusted to 8.3 or lower using a 5% sodium bicarbonate solution until no
color change occurs with phenolphthalein. This adjusted solution is recognized as
the only hypochlorite preparation approved for use as an antibacterial on tissues.

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Inorganic Pharmaceutical Chemistry: Topical Agents

The alkalinity and oxidizing action of this solution is too strong for use on tissues.
In addition, the solution dissolves blood clots and delays healing.

Solutions of sodium hypochlorite are strong oxidizing agents, as can be shown by
the liberation of free iodine from solutions of potassium iodide.

2KI + NaClO + H2O ⟶ 2KOH + NaCl + I2

The antibacterial properties of sodium hypochlorite solutions are due in part to the
liberation of chlorine and to the oxidizing action produced by the liberation of
oxygen by forming hypochlorous acid when reacted with water.

NaOCl + H2O ⟶ HOCl + NaOH

In Diluted Sodium Hypochlorite Solution, the pH is reduced through the addition
of sodium bicarbonate solution. This has the effect of reducing the caustic action of
the highly alkaline solution on tissues and of increasing the effective concentration
of hypochlorous acid. The bicarbonate acts to reduce the hydroxide ion
concentration according to the reaction shown:

HCO3− + OH− ⟷ CO32− + H2O

The primary uses for hypochlorite solutions:

 Sodium Hypochlorite Solution is useful as a disinfectant and laundry bleach.
 Diluted Sodium Hypochlorite Solution, N.F. XIII, has been used in the past
as an antiseptic on pus-forming (suppurating) wounds. It has the
disadvantages of dissolving certain types of sutures, and of dissolving blood
clots and prolonging clotting time.
 The solution may also be used as a foot bath in the prevention of various
fungal infections (athlete’s foot, etc.).

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Inorganic Pharmaceutical Chemistry: Topical Agents

 The antibacterial effectiveness may be increased by acidifying the solution
at the time of use, thereby further increasing the concentration of HOCl.

3- Iodine Solution

Both Iodine Solution and Iodine Tincture contain the same concentrations of
ingredients, they differ only in the nature of the solvent, i.e., Iodine Solution is
aqueous, having been prepared with purified water, and Iodine Tincture contains
approximately 50% alcohol as the final solvent. Both solutions are transparent,
have a reddish-brown color, and have the characteristic odor of iodine. Iodine
Tincture also has the odor of alcohol. The active antimicrobial agent common to
both preparations is iodine.

The most notable chemical property of iodine in aqueous solution is that of a mild
oxidizing agent. It is believed that the oxidizing action is mediated through the
formation of hypoiodous acid [HIO].

I2 + H2O ⇌ HI + HIO ⟶ HI + (O)

It will oxidize iron to form ferrous iodide.

Fe + I2 ⟶ FeI2

For this reason, metal spatulas should not be used to handle iodine, and balance
pans should be protected against pitting by using weighing papers.

Iodine is a very active element and is, therefore, easily inactivated by organic
materials in the gastrointestinal tract. Most of the toxicity due to the ingestion of
large quantities of iodine is a result of the corrosive action of the element on the
gastrointestinal tract, producing abdominal pain, gastroenteritis, and possibly
bloody diarrhea. The treatment usually involves gastric lavage with a soluble
starch solution or administration of a 5% sodium thiosulfate solution. The starch

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Inorganic Pharmaceutical Chemistry: Topical Agents

solution forms a complex with the iodine (purple color), thus aiding in its removal
from the stomach.

2Na2S2O3 + I2 ⟶ Na2S4O6 + 2NaI

The primary uses of iodine solutions:

 Iodine Tincture and Iodine Solution are probably the most effective topical
antiseptic agents available. There is some indication that Iodine Tincture
may be more suitable for this purpose, since the alcohol seems to improve
the penetration of the iodine.
 Iodine Solution is preferred for application to wounds because the alcohol in
the Tincture is very irritating to open tissue.
 Iodine Tincture may be used to disinfect drinking water.
 Povidone-Iodine is a member of a class of compounds referred to as
Iodophors, these are complexes of iodine, with carrier organic molecules
serving as a solubilizing agent. These complexes slowly liberate iodine in
solution. The major advantage to their use is the lack of tissue irritation,
which makes them useful for application to sensitive areas and mucous
membranes.

4- Silver Nitrate (AgNO₃; Mol. Wt. 169.87)

Silver Nitrate occurs as colorless or white crystals which become gray or grayish
black on exposure to light in the presence of organic matter. It is very soluble in
water, sparingly soluble in alcohol, and freely soluble in boiling alcohol.

Solutions of silver nitrate in concentrations between 0.5 and 1.0% are used as
antibacterial agents. The chemistry and pharmacological action of these
preparations are essentially those of the silver ion. The only salts of silver are those

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Inorganic Pharmaceutical Chemistry: Topical Agents

of the monovalent cation [Ag(I)]. This ion is readily obtained from metallic silver
through treatment with an oxidizing acid, e.g., cold dilute nitric acid.

3Ag + 4HNO₃ → 3AgNO₃ + NO↑ + 2H₂O

The protein precipitant action of silver ion is not selective; it will precipitate both
bacterial and human protein. The range of activity available includes antibacterial,
astringent, irritant, and corrosive, depending upon the concentration applied. Silver
ion precipitation of protein involves interactions between the cation and various
polar groups on the protein molecule, e.g., –SH, –NH₂, –COOH, and heterocyclic
residues, e.g., histidine. When applied to tissue in a concentration of 0.1% Ag ⁺ the
activity is rapidly bactericidal.

Extended use of silver preparations is likely to cause a darkening of the skin due to
the deposition of free silver below the epidermis. This condition is termed argyria
and is essentially irreversible.

The primary uses of silver nitrate products:

 It is employed as an antibacterial in solutions ranging in concentration from
0.01 to 10%, recognizing that the higher concentrations present astringent
and irritant properties to the tissues.
 Silver Nitrate Ophthalmic Solution is a 1% solution for instillation into the
eyes of newborn babies. Silver salts are quite effective against gonococcal
organisms, and two drops of this solution are placed in each eye as a
prophylactic measure against (ophthalmia neonatorum).
 Silver nitrate is applied as of 0.5% aqueous solution in the form of a wet
dressing on burned areas of patients suffering from third-degree burns.

Astringents Agents

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Inorganic Pharmaceutical Chemistry: Topical Agents

Astringents are compounds that cause protein precipitation on the surface of cells,
resulting in the coagulation of proteins and tissue constriction without causing deep
damage. They typically act on small blood vessels (smooth muscle) and are applied
topically. Astringents have limited penetration, causing a mild antimicrobial effect
and restricting blood flow, but they don't result in the death of cells.

Uses of Astringents:

 Styptic action: Stops bleeding from small cuts by promoting blood
coagulation and constricting capillaries.
 Antiperspirant: Decreases the secretion of sweat.
 Constricts mucous membranes: Reduces inflammation by limiting blood
flow to the surface.
 Topical actions: Removes unwanted tissue or restricts protein action, often
used at higher concentrations as a corrosive agent.

Common astringent products include aluminum, zinc, and zirconium salts.

1- Aluminum Chloride (AlCl₃·6H₂O):

It acts as a Lewis acid and is very soluble in water, alcohol, and glycerin,
producing an acidic solution. It is used in aqueous solutions as an astringent and
mild antiseptic, with concentrations ranging from 10% to 25%. It can cause
irritation to tissue due to the hydrolysis of the aluminum chloride forming
hydrochloric acid (HCl). This compound was initially used as an antiperspirant but
was too irritating and could damage clothing.

2- Aluminum Hydroxy chloride:

This term refers to two possible compounds: monohydroxy chloride and dihydroxy
chloride, which are both acidic but less soluble in water than aluminum chloride.

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Inorganic Pharmaceutical Chemistry: Topical Agents

These compounds are less irritating and are commonly used in commercial
antiperspirants. They replace the more irritating aluminum chloride in products
such as deodorant sprays, creams, and solutions, used in concentrations around
20%.

3- Zinc Chloride

Zinc chloride solutions are acidic due to hydrolysis, which forms hydrochloric acid
(HCl) and basic zinc chloride, as shown in the equation:

ZnCl2 + H2O ⇌ Zn(OH)Cl +H+ + Cl−

It is important to filter zinc chloride solutions through asbestos or glass wool as
they can dissolve materials like paper and cotton. Zinc chloride is used to form
zinc oxychloride when mixed with zinc oxide. This creates a hard mass, which is
used in some dental cements.

Uses of Zinc Chloride:

 Astringent & Antiseptic: Zinc chloride acts as a powerful protein precipitant,
making it a strong astringent and mild antiseptic.

 Escharotic Action: The compound also acts as an escharotic, aiding in tissue
sloughing and scar tissue formation, which helps in healing.

 Nasal Spray & Sinus Treatment: In lower concentrations (0.5 to 2%), zinc
chloride solutions are applied to mucous membranes or used as nasal sprays
to aid sinus drainage.

 Dentin Desensitizer: A 10% solution of zinc chloride is applied to teeth to
act as a desensitizer of dentin.

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