Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics PDF

Summary

This document discusses inorganic pharmaceutical chemistry, focusing on protectives, adsorbents, and cathartics used in treating mild diarrhea. It explains the mechanisms of adsorption and factors influencing it, including surface area, porosity, and polarity. Different types of gastrointestinal agents and their roles in treating diarrhea are also detailed.

Full Transcript

Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

This group of gastrointestinal agents is commonly used for the treatment of mild
diarrhea. Diarrhea is a symptom and not a disease. Very briefly, it results when
some factor impairs digestion and/or absorption, thereby increasing the bulk of the
intestinal tract. This increased bulk stimulates peristalsis, propelling the intestinal
contents to the anus. Diarrhea may be acute or chronic.

Acute diarrhea can be caused by bacterial toxins, chemical poisons, drugs, allergy,
and disease. The effects of these agents range from tissue damage or irritation to
that of causing electrolytes to flow from body fluids into the intestinal tract.
Chronic diarrhea can result from gastrointestinal surgery, carcinomas, chronic
inflammatory conditions, and various absorptive defects. Frequently the causative
factor of acute diarrhea is not found, and the patient shrugs it off as a 24- or 48-
hour stomach flu.

Diarrhea is a serious condition, particularly for very young or elderly patients. The
loss of fluids and electrolytes can quickly lead to dehydration and electrolyte
imbalances. The antidiarrheal agents described in this chapter will only treat the
symptoms and occasionally the cause, but they will not treat the complications.
Most products for the treatment of diarrhea will consist of an adsorbent-protective,
an antispasmodic, and possibly an antibacterial agent. The ideal antispasmodic
agent should act directly on the smooth muscles of the gut to produce a spasm-like
effect which decreases peristalsis and increases segmentation. The antibacterials
are only effective if there is an actual infection in the intestinal tract or during
epidemics previously shown to be caused by a microorganism. The adsorbent-
protectives supposedly adsorb toxins, bacteria, and viruses along with providing a
protective coating of the intestinal mucosa. They include bismuth salts, special
clays, and activated charcoal.

1
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

Mechanism of Adsorption

Adsorption is a process by which a substance (the adsorbate) adheres to the surface
of another substance (the adsorbent). In the case of gastrointestinal protectives and
adsorbents, substances like activated charcoal, kaolin, and certain clays (e.g.,
attapulgite) act as adsorbents by binding toxins, gases, and bacteria in the gut.

Types of Adsorption

Physical Adsorption: This occurs due to Van der Waals forces, which are weak,
non-specific forces that attract molecules to the surface of the absorbent. Physical
adsorption is generally reversible and does not involve chemical bonding.

Chemical Adsorption: Involves the formation of stronger chemical bonds between
the adsorbent and adsorbate. This type of adsorption can be irreversible and
involves the exchange or sharing of electrons between the adsorbent and the
adsorbate. For example, bismuth compounds can chemically interact with toxins in
the gastrointestinal tract, reducing irritation and inflammation.

Factors Affecting Adsorption

1. Surface Area and Porosity: Adsorbents like activated charcoal are characterized
by high surface areas and porous structures. For instance, one gram of activated
charcoal can have a surface area of over 1,000 square meters. This massive surface
area allows for a higher amount of substance to be adsorbed.

2. Polarity: Adsorption is affected by the polarity of the molecules. Polar
adsorbents, such as certain clays, will more effectively adsorb polar molecules like
water and electrolytes, while non-polar adsorbents like activated charcoal will be
more effective at binding non-polar substances such as lipophilic drugs and toxins.

2
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

3. pH Sensitivity: The pH of the surrounding environment can influence the
efficiency of adsorption. For example, the adsorption of bismuth salts can vary
based on the pH of the stomach or intestines, as certain compounds become soluble
depending on the pH level.

Bismuth-Containing Products.

The use of bismuth salts as antidiarrheals seems to be supported chiefly by
tradition. Bismuth sub carbonate has also found some use as antacid. Although the
bismuth salts used as antidiarrheals are water-insoluble, a small amount does go
into solution. The soluble bismuth cation supposedly exerts a mild astringent and
antiseptic action, but it is doubtful whether this is clinically significant. Intestinal
hydrogen sulfide acts upon the bismuth salts to form bismuth sulfide; hence, the
black stools resulting from the oral administration of bismuth-containing
preparations. These compounds provide a dual action, adsorbing toxins and
bacteria while forming a protective barrier in the intestines.

2Bi3+ + 3H2S → Bi2S3 (black precipitate) + 6H+

1. Bismuth Subnitrate, N.F. XIII (approximate formula:
[Bi(OH)2NO3]4·BiO(OH))

Bismuth Subnitrate occurs as a white, slightly hygroscopic powder which gives an
acid reaction using blue litmus paper. It is practically insoluble in water and in
alcohol but is readily dissolved by hydrochloric or nitric acid. It is assayed in terms
of bismuth trioxide (Bi2O3).

Bismuth subnitrate has a well-recognized incompatibility with tragacanth, in which
tragacanth precipitates as a hard mass in the presence of the salt.

3
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

An interesting paper in connection with this incompatibility points out that the
difficulty may be overcome by the protective action of sodium biphosphate or
trisodium phosphate. These authors feel that because tragacanth is a negative
colloid, the adsorption of the positive bismuth ion (without corresponding
adsorption of the negative nitrate ions) tends to precipitate the colloid. The use of
phosphates is based on their supplying the negative ions lacking, which may then
be adsorbed by the tragacanth, stabilizing the colloid.

Bismuth subnitrate apparently can inhibit pepsin. However, its main use is as a
component of Milk of Bismuth, where it probably functions as a mild astringent-
protective

Milk of Bismuth

Milk of Bismuth contains bismuth hydroxide and bismuth sub carbonate in
suspension in water. It is made by converting bismuth subnitrate to bismuth nitrate
[Bi(NO₃)₃] by the addition of nitric acid. Then, by treatment with ammonium
carbonate and ammonia solution, bismuth nitrate is converted to bismuth
hydroxide and sub carbonate.

Chemical Reactions:

NH₂CO₂NH₄·NH₄HCO₃ + NH₄OH ⇌ 2(NH₄)₂CO₃

3(NH₄)₂CO₃ + 2Bi(NO₃)₃ → Bi₂(CO₃)₃ ↓ + 6NH₄NO₃

2Bi₂(CO₃)₃ + H₂O → [(BiO)₂CO₃]₂·H₂O + 4CO₂ ↑

Bi(NO₃)₃ + 3NH₄OH → Bi(OH)₃ ↓ + 3NH₄NO₃

It is classified by the National Formulary as an astringent and antacid.

4
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

2. Bismuth Sub carbonate, U.S.P. XVIII (approximate formula:
[(BiO)₂CO₃]₂·H₂O)

Bismuth sub carbonate is a white or pale yellowish white, odorless, tasteless
powder, which is stable in air, but is slowly affected by light. It is practically
insoluble in water and in alcohol but dissolves completely in nitric acid and in
hydrochloric acid, with copious effervescence. Bismuth sub carbonate is assayed in
terms of bismuth trioxide (Bi₂O₃).

Nonofficial Bismuth Compounds

1. Bismuth Subgallate
2. Bismuth Subsalicylate
3. Bismuth Ammonium Citrate

Activated Clays and Other Adsorbents. This group is composed mostly of clays
which have excellent adsorbent properties, and most of them are used for that
purpose industrially. They appear to have a valid clinical use, at least in mild
diarrhea of short duration.

1. Kaolin

Kaolin is a native hydrated aluminum silicate, powdered and freed from gritty
particles. It occurs as a soft, white, or yellowish white powder, or as lumps. It has
an earthy or clay-like taste. Kaolin binds toxins and bacteria through both physical
and chemical adsorption. Kaolin is insoluble in water, in cold diluted acids, and in
solutions of the alkali hydroxides. It is usually found together with the vegetable
carbohydrate, pectin (Kaopectate®, Kao-Con®) and used as an adsorbent. Kaolin-
containing products have been reported to interfere materially with the intestinal
absorption of lincomycin.

5
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

2. Activated Charcoal

Activated charcoal has been used as an adsorbent in the treatment of diarrhea. It is
now a recommended antidote in certain types of poisoning. It works primarily
through physical adsorption. It is highly porous and effective in binding large
organic molecules such as bacterial toxins, chemicals, and drugs.

SALINE CATHARTICS
Saline cathartics (purgatives) are agents that quicken and increase evacuation from
the bowels. Laxatives are mild cathartics. Most can be purchased without a
prescription and are a group that has been widely used, abused, and often
overpromoted by the manufacturer.

The 1971 A.M.A. Drug Evaluations states that cathartics are properly used to:

(1) ease defecation in patients with painful hemorrhoids or other rectal
disorders, and to avoid excessive straining and concurrent increases in
abdominal pressure in patients with hernias.
(2) avoid potentially hazardous rises in blood pressure during defecation in
patients with hypertension, cerebral, coronary, or other arterial diseases.
(3) relieve acute constipation.
(4) remove solid material from the intestinal tract prior to certain
roentgenographic studies.

Laxatives should only be used for short-term therapy as prolonged use may lead to
loss of spontaneous bowel rhythm upon which normal evacuation depends, causing
the patient to become dependent on laxatives, the so-called "laxative habit."

Constipation is the infrequent or difficult evacuation of feces. It may be due to a
person resisting the natural urge to defecate, causing the fecal material which

6
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

remains in the colon to lose fluid and to become relatively dry and hard.
Constipation can also be caused by intestinal atony (lack of muscle tension),
intestinal spasm, emotions, drugs, and diet.

Basically, there are four types of laxatives:

(1) The stimulant laxatives act by local irritation on the intestinal tract, which
increases peristaltic activity. They include phenolphthalein, aloin, cascara extract,
rhubarb extract, senna extract, podophyllin, castor oil, 1,8-dihydroxyanthraquinone
(danthron), oxyphenisatin, bisacodyl, and calomel (no longer used).

(2) The bulk-forming laxatives are made from cellulose and other nondigestible
polysaccharides. They swell when wet, with the increased bulk stimulating
peristalsis. Included in this group are psyllium seed, methyl cellulose, sodium
carboxymethylcellulose, and karaya gum.

(3) The emollient laxatives act either as lubricants facilitating the passage of
compacted fecal material or as stool softeners. Mineral oil is the main lubricant
laxative used, and d-octyl sodium sulfosuccinate, an anionic surface-active agent,
is the most used stool softener.

(4) The saline cathartics act by increasing the osmotic load of the gastrointestinal
tract. They are salts of poorly absorbable anions and sometimes cations. The body
relieves the hypertonicity of the gut by secreting additional fluids into the intestinal
tract. The resulting increased bulk stimulates peristalsis. Poorly absorbed anions
that are used as saline cathartics are biphosphate (H₂PO₄⁻), phosphate (HPO₄²⁻),
sulfate, and tartrate. The saline cathartics are water soluble and are taken with large
amounts of water. This prevents excessive loss of body fluids and reduces nausea
and vomiting if a too hypertonic solution should reach the stomach.

7
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

The saline cathartics, when taken for brief periods, are relatively free of side
effects. Over a longer term, patients on low-sodium diets should not use the
sodium-containing saline cathartics (sodium biphosphate, sodium phosphate,
sodium sulfate, and potassium sodium tartrate). For those with impaired renal
function, the magnesium salts should be restricted, since some magnesium cation is
absorbed. Magnesium has a central nervous system depressant effect.

Official Saline Cathartics

1. Sodium Biphosphate occurs as colorless crystals or as a white, crystalline
powder. It is odorless and is slightly deliquescent. Its solutions are acid to litmus
and effervesce with sodium carbonate. When saline cathartics, like sodium
biphosphate (NaH₂PO₄) dissolve in water, they dissociate into their respective
ions:

NaH2PO4 → Na+ + H2PO4−

H₂PO₄⁻ + H₂O ⇌ H₃O⁺ + HPO₄²⁻

Although classified by the National Formulary as a urinary acidifier, it is also used
as a cathartic (Phospho-Soda, Vacuetts, and Sal Hepatica).

2. Sodium Phosphate occurs as a colorless or white granular salt which
effervesces in warm, dry air. Its solutions are alkaline, with a 0.1 M solution
having a pH of about 9.5. It is freely soluble in water and very slightly soluble in
alcohol. Because of the poor intestinal permeability of the monohydrate phosphate
anion, this product is widely used as a saline cathartic (Fleet Enema, Phospho-
Soda).

8
Inorganic Pharmaceutical Chemistry: Protectives, Adsorbents and Cathartics

Na2HPO4 → 2Na+ + HPO42−

3. Dried Sodium Phosphate is a nearly anhydrous white powder which readily
absorbs moisture. It is freely soluble in water and insoluble in alcohol. It is used as
a saline cathartic in Effervescent Sodium Phosphate, which is a mixture of sodium
bicarbonate, tartaric acid, and citric acid. When dissolved in water, a carbonated
solution of sodium phosphate, sodium tartrate, and sodium citrate is obtained.
Sodium tartrate is also a saline cathartic, and sodium citrate provides a lemon-like
flavor which, along with the carbonation provided by the carbon dioxide, masks
the saline taste.

NaH2PO4 + NaHCO3 → Na2HPO4 + CO2 + H2O

Dried Sodium Phosphate is used because the heptahydrate salt of Sodium
Phosphate would cause a premature reaction between the sodium bicarbonate and
tartaric and citric acids, yielding a product with a flat, saline flavor.

Best of Luck

9