Quality Control of Medicinal Plants Part II PDF

Summary

This document details procedures for the standardization and quality evaluation of herbal drugs. It covers plant material, sampling, moisture content, and various methods for moisture determination, including gravimetric, chemical, and spectroscopic techniques. The document also discusses extractive values, ash values (total, acid-insoluble, and water-soluble), crude fiber, volatile oil determination, tannin content, and bitterness value.

Full Transcript

Quality Control of Medicinal Plants Part II

List the procedures utilized for the Standardization and Quality
evaluation of Herbal drugs.

Mention the cases in which each procedure is used.
 Plant material
Plant materials fulfil diverse roles, encompassing:
Home remedies
Over-the-counter drug products
As essential ingredients in the pharmaceutical industry.
Homeopathic remedies

They constitute a significant share of the worldwide drug market.Consequently,
the assessment of medicinal plants holds great significance. This process
encompasses the identification of the material and the assessment of its quality
and purity.
To facilitate this evaluation>> a range of numerical standards is outlined in
pharmacopoeias and other authoritative publications, such as the WHO manual
https://iris.who.int/bitstream/handle/10665/42052/9241545178.pdf?sequence=1
Standardization & Quality Evaluation of Herbal drugs

PHYSICAL
QUALITY EVALUATION OF
HERBAL DRUGS

What does this test give information
 Sampling
In some pharmacopoeias and in the WHO manual.

Preliminary examination

In the case of whole drugs macroscopical and sensory characters are usually
sufficient to enable the drug to be identified.
The price of certain drugs depends largely on such factors as size and color,
which are not necessarily related to therapeutic value. This applies to such
important drugs as senna leaflets, senna pods, chamomile flowers, ginger,
nutmegs and rhubarb
Considerable care must be exercised to ensure that this sample is truly
representative.
Methods of sampling are fully described.
 Moisture content

❑Moisture, in conjunction with temperature, activates enzymes and provides
suitable conditions for the proliferation of living organisms.

❑All drugs are at risk of decaying if the humidity in the drug material exceeds
15%.

❑However, different levels of moisture are acceptable for each drug.

❑The moisture content is especially important for material which absorbs
moisture easily or deteriorates quickly in the presence of water, as in cases
of drugs containing glycosides (cleavage of glycosidic linkage).
 Determination of moisture

1. Gravimetric method based on the loss on drying.
2. Separation and measurement of moisture.
3. Chemical methods
4. Spectroscopic methods

1. Gravimetric method based on the loss on drying.
Direct drying involves heating a drug sample at 100-105 C until its weight
becomes constant.
[Although the loss in weight principally is due to water, small amounts of other
volatile materials will also contribute to weight loss, so this method is suitable
for drugs containing little or no volatile material, such as digitalis and aloes.
 Determination of moisture
Drying of Heat-Sensitive Food Components
Certain food products contain components, such as fructose, which can
undergo decomposition when exposed to temperatures as low as 100°C
under standard atmospheric pressure. In such cases, it is advisable to employ a
vacuum oven operating at a reduced pressure of 70C for the purpose of drying.
Drying Substances with Volatile Constituents
A specialized approach is utilized for substances that possess a notable
concentration of volatile constituents, like balsamic materials.
This approach involves applying a thin layer of the weighed substance onto
glass plates, followed by placement within a desiccator. Within the desiccator,
phosphorus pentoxide serves as the desiccating agent ‫ﻣﺎدة ﻣﺠﻔﻔﮫ‬. This process
can be conducted under either standard atmospheric pressure or reduced
pressure conditions.
 Determination of moisture

2. Separation and measurement of moisture

To enhance the precision of moisture determination,
specialized techniques within the loss-on drying method can
isolate and quantify the water content extracted from a
given sample.
One effective approach involves passing a dry inert gas
through the heated sample and utilizing a dedicated
absorption system designed specifically for water. This setup
facilitates the collection of the moisture transported by the
gas stream.
 Determination of moisture

❑Gas chromatographic GC methods are important for moisture
determination because of their specificity and efficiency.

❑The water in the weighed, powdered sample can be extracted with dry
methanol and an aliquot‫ اﻟﻌﯿﻨﮫ‬submitted to chromatography on a suitable
column.

❑The water separated by this means is readily determined from the resulting
chromatogram.
3-Chemical methods for the determination of moisture
The Karl Fischer titration is a widely used method for the accurate
determination of moisture content in various substances. It's especially
valuable for samples with low moisture content and is commonly
employed in chemistry, pharmaceuticals, and the food industry. Here's
an overview of the Karl Fischer procedure for moisture determination:

Principle: Karl Fischer titration is based on the reaction between water
(moisture) and a Karl Fischer reagent, which is a specialized chemical
solution designed to react quantitatively with water. The reaction is
usually iodometric and involves the following reaction:

H2O + I2 + SO2 + RNH2 → RNH3+ + HSO4- + I-
4-Spectroscopic methods

Water will absorb energy at various wavelengths throughout the
electromagnetic spectrum, and this fact can be made a basis for its quantitative
determination.
Measurements can be made in both infrared and ultraviolet regions; interfering
substances must be absent.
The method is particularly suitable for very small quantities of water (trace
quantities in gases).
Nuclear magnetic resonance (NMR) spectroscopy has been employed for the
determination of moisture in starch, cotton and other plant products.
Ultraviolet-visible (UV-Vis) spectroscopy
 Extractive values
The determination of water-soluble or ethanol-soluble extractives is used
as a means of evaluating drugs, the constituents of which are not readily
estimated by other means.

In certain cases, extraction of the drug is by maceration, in others by
a continuous extraction process (Soxhlet extractor).

The extract of a certain amount of
the drug is then evaporated, dried and
weighed.

Please watch the following video
SOXHLET EXTRACTION with Dr. Mark Niemczyk, Ph.D. (youtube.com)
Soxhlet extractor
 Ash values

When vegetable drugs are incinerated, the organic matter is burnt away, and an
inorganic residue is left, which is known as ash.

The ash figure for each drug is considered as a general measure of quality and it
is usually given for each drug in the pharmacopeia.

The ash determinations are useful for detecting law-grade products, exhausted
drugs and excess of sandy or earthy matter especially in powdered drugs.

The pharmacopeias use different types of ash figure as total ash, acid-insoluble
ash and water-soluble ash.
 Total ash

The total ash method is designed to measure the total amount of
material remaining after ignition‫اﺷﺘﻌﺎل‬. This includes both
‘physiologic ash’, which is derived from the plant tissue itself, and
‘non-physiologic ash’, which is the residue of the extraneous
matter (e.g. sand and soil) adhering to the plant surface.

The total ash usually consists mainly of carbonates, phosphates,
silicates and silica.

To determine the total ash, a certain amount of the drug is
incinerated to a constant weight. The ash is weighed, and the
percentage is calculated.
 Acid-insoluble ash

Acid-insoluble ash is the residue obtained after boiling the total
ash with dilute HCl and igniting the remaining insoluble matter.
This measures the amount of silica present, especially as sand
and siliceous earth.

A high acid-insoluble ash in drugs such as senna, cloves, and
licorice indicates contamination with earthy material.

The ash dissolved in acid consists mainly of oxides and carbonates
and is termed acid-soluble ash which is calculated by difference.
 Water-soluble ash

Water-soluble ash consists mainly of the water-soluble oxides and
carbonates of sodium and potassium.

It is the difference in weight between the total ash and the residue
after treatment of the total ash with water.

It is used to detect drugs exhausted by water, e.g. spent ginger,
exhausted tea and liquorice.
 Crude fiber
The preparation of crude fibre is a means of concentrating the more resistant
cellular material of drugs for microscopical examination.

It is particularly useful for rhizomes as ginger which contain relatively large amounts
of oleoresin and starch ( which interfere with microscopic examination).

The technique involves defating the powder and boiling in turn with standard acid
and alkali with suitable washing of the insoluble residue obtained at the different
stages.

The crude fiber so obtained can also be employed quantitatively to assay the fiber
content of foods and to detect excess of certain materials in powdered drugs, e.g.
clove stalk in clove.
 Determination of volatile oil

Minimum standards for the percentage of volatile oil present in a
number of drugs are prescribed by many pharmacopeias.

A distillation method is usually employed using a suitable apparatus.
The recovered distillate is collected in the graduated tube, which already
contains a known amount of xylene (European Pharmacopoeia, WHO
manual).

Vol. of volatile oil = total vol.- vol. of xylene
 Tannin content

Tannins are substances capable of turning animal hides into leather by
binding proteins to form water-insoluble substances that are resistant to
proteolytic enzymes.
This process, when applied to living tissue, is known as an “astringent”
action and is the reason for the therapeutic application of tannins.
Tannins (polyphenols) are easily oxidized and polymerized in solutions; if
this happen they lose much of their astringent effect.
A few drugs are assayed for their tannin content. The method refers to
those polyphenols adsorbed by hide powder and giving a color reaction
with sodium phosphomolybdotungstate reagent.
 Bitterness value

Medicinal plant materials that have a strong bitter taste (bitters) are employed
therapeutically, mostly as appetizing agents. Their bitterness stimulates
secretions in the gastrointestinal tract, especially of gastric juice.

Bitter substances can be determined chemically. However, science they are
mostly composed of two or more constituents with various degrees of
bitterness, it is first necessary to measure total bitterness by taste.

The bitterness value is determined organoleptically by comparison with a
quinine hydrochloride solution which acts as the standard.

One of the most intensely bitter natural compounds is amarogentin, which has a
bitterness value of 58,000,000. This means that you would need to dissolve one
part of amelogenin in 58,000,000 parts of water to make its bitter taste no
longer perceptible.
 Swelling index

This is defined in the BP as the volume in millilitres occupied
by 1 g of a drug, including any adhering mucilage after it has
swollen in an aqueous liquid for 4 h.
The drug is treated with 1 ml of ethanol (96%) and 25 ml
water in a graduated cylinder, shaken every 10 min for 1h and
allowed to stand as specified.
The standard can be determined on the whole drug (linseed
and psyllium) or on the powder (marshmallow root).
 Rf values

Pharmacopoeias are increasingly employing thin-layer chromatography as a
means for assessing quality and purity.

The Rf value ( rate of flow, distance moved by solute divided by distance moved
by solvent front) of a compound, determined under specific conditions, is
characteristic and can be used as an aid to identity.

Quantitative extracts of crude drugs are prepared and compared
chromatographically with standard reference solutions of the known
constituents.
In an analogous manner, GC retention times and peak areas can be employed for
the examination of volatile oils and other mixtures.
 Toxic residues

Pesticides may arise in crude drugs as a result of pesticide
application during cultivation and at a late stage from fumigation
of the stored product.
Appendix XI L of the BP 2000 gives the requirements relating to
pesticide residues for herbal drugs; specific directions for the
sampling of bulk materials are given and the various pesticides
and their assays listed.
Aflatoxins' presence in plant material can be hazardous to health
if absorbed even in very small amounts. Therefore, they should be
determined.
Radioactive impurities at a certain amount can not be avoided as
a result of exposure to naturally occurring radionuclitides.
Dangerous contamination may be the consequence of a nuclear
accident.
 Standards applicable to volatile and fixed oils

Certain standards are particularly appropriate for volatile and fixed
oils:
(assess the identity and purity of oils).

1. Refractive index
2. Optical rotation
3. Quantitative chemical tests
 Refractive index
The refractive index of a substance is determined by comparing the speed of light
in air to its speed in the substance being examined. Therefore, the refractive
index is influenced by temperature, and standard measurements in
pharmacopoeias are typically conducted at 20°C.

=

Automatic refractometers such
as Leica Auto Abbe’ refractometer
 Refractive index

❑Measurements of refractive index are particularly valuable for purity
assessments of volatile and fixed oils.
❑Many values can be found in EP, BP, BPC and other pharmacopoeias.
❑Oils of cassia, cinnamon and cinnamon leaf have refractive indices of about 1.61,
1.573-1.6 and about 1.53, respectively, making possible differentiation of the oils.
 Optical rotation

❑The optical rotation of a liquid refers to the extent by which the plane of
polarized light turns when it passes through the liquid sample. This rotation can
occur in two directions:
❑Clockwise, known as dextrorotatory.
❑Anticlockwise, known as levorotatory.
❑The magnitude and direction of the observed rotation depend on various factors,
including:
The characteristics of the light source used for the experiment.
Temperature.
The thickness of the sample layer being analyzed.
Thank you