Application of microscopic techniques for the authentication of herbal
medicines
Zhongzhen Zhao
School of Chinese Medicine, Hong Kong Baptist University, Kowloon, Hong Kong
Microscopic identification is the method most commonly used to authenticate Chinese herbal medicines. By means of
various microscopic techniques, structural and cellular features of herbs are examined in order to determine their botanical
origins and assess their qualities. This method is useful for identifying species from fragments or powders and for
distinguishing species with similar morphological characters; it may also be useful for evaluating the pharmaceutical
quality of herbs. In this chapter, techniques of preparing specimens for microscopic examination are described. Normal
light microscopy combined with polariscope and fluorescence microscopy are introduced as they are used in the
authentication of Chinese herbal medicines. Structures and cells of herbs have been found to possess stable and specific
polariscopic and fluorescent characteristics that can be used to determine the botanical identify of herbal medicines. In
addition, the future prospect of combining microscopes with chemical analysis to analyze the chemical profiles of herbal
tissues is discussed. Establishing a correlation between microscopic features and active components distributed in a plant’s
tissues will enable quality evaluation of Chinese herbal medicines by microscopy.
Keywords Chinese herbal medicine; authentication; polariscope; fluorescence microscope
1. Introduction
Herbal medicines are being used more and more widely throughout the world. Among these, Chinese herbal medicines
(CHMs) are among the most popular. This trend poses two new problems, with international implications, which
increase the importance of fast, accurate, and efficient means of authenticating herbs. First, the growing market for
CHMs worldwide has spawned many CHMs trading companies and generated an increase in not only counterfeit herbs
but also herbs of questionable quality. Second, Chinese herbal medicines differ in significant ways from their Western
herbal counterparts, raising different problems of quality control and traceability. CHMs are often processed. That is,
the crude drug may undergo a series of treatments that render it chemically different from the source drug. Second,
CHMs are often taken as complex prescriptions of ten, twenty or even thirty different components. These unique
features of CHMs generate equally unique problems of authentication, such as determining if there is species confusion
of different herbs sharing one name or one herb using different names and if the correct CHMs have been included in a
particular proprietary medicine. As poisoning incidents have been caused by misuse or confusion of CHMs, their safe
use has raised international concern, and authentication of CHMs is critical to their safe and effective use [1].
Today, there are a variety of methods available to authenticate CHMs, ranging from simple morphological
examination to physical and chemical analysis, and DNA molecular biology. Each method has drawbacks and
advantages. In difficult or critical cases, sometimes two or several methods are applied for the authentication of CHMs.
Nevertheless, ordinary light microscopy is still the most practical method for primary authentication. It has been
commonly used in the authentication of herbal medicines in China and many other countries because of its virtues of
small amount of sample needed, fast speed and low cost. Furthermore, herbal medicines are mostly low cost medicine,
which should not be raised in price as a consequence of the application of unnecessary highly sophisticated methods for
authentication. In China it has been used in the authentication of CHMs since the 1953 edition of the Chinese
Pharmacopoeia was published [2]. Many reference books of CHMs still record the microscopic characteristics of each
CHM, e.g., Chinese Materia Medica [3] and New Compendium of Chinese Materia Medica [4]. Outside China, the
pharmacopoeias of other countries also record the microscopic characteristics of their herbal medicines, for examples,
European Pharmacopoeia [5], British Pharmacopoeia [6], United States Pharmacopeia [7], Japanese Pharmacopoeia [8],
Ayurvedic Pharmacopoeia of India [9] and Vietnamese Pharmacopoeia [10].
Using the microscope to determine the identity of herbal medicines, namely, microscopic authentication, refers to
observing cell structure and internal features using a microscope and its derivatives. Besides the ordinary light
microscope, other microscopes also have been used to enhance the accuracy of authentication, such as the polarized
light microscope and fluorescence microscope. Use of these microscopes expands the number of features available for
use in identification. For example, it has been found that starch grains, crystals of calcium oxalate, stone cells, vessels
and fibres have stable and special polariscopic characteristics [11, 12]. The fluorescence microscope reveals the
fluorescence emitted from herbal tissues under illumination. Many herbal tissues, by virtue of their chemical structures
or secondary metabolites, have the ability to emit light of a specific wavelength following the absorption of light with a
shorter wavelength and higher energy [13]. For example, in recent years, the fluorescence microscope has been applied
for distinguishing the medicinal herb Oldenlandia diffusa from other species of the same genus which are confused with
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it in herbal markets [14]. Elsewhere, the fluorescence microscope and microspectrometer have been used to authenticate
four kinds of powdered CHMs and measure the distribution of chemicals in the cross sections of CHMs [15].
Recent innovations in normal light microscopy have greatly enhanced its usefulness in the authentication of herbal
medicines. Feature extraction and similarity measurement as well as the use of chord length distribution have been used
effectively in the classification of starch grains in microscopic images of CHMs. This provides greater accuracy and
flexibility in capturing information about starch grains which are useful in authentication of CHMs [16, 17]. A novel
method which combines histological and microscopic analysis of laticifers by "blob" analysis has been established to
distinguish species of Radix Fici (Wuzhimaotao in Chinese name) which were otherwise difficult to distinguish by
microscopic examination; the method provides objective data to describe and standardize the characters observed in
microscopic images [18].
Microscopic techniques have been widely and effectively applied for the authentication of herbal medicines. In this
chapter, the standard procedures and application of microscopic identification will be described, and the future
prospects for this work will be discussed.
2. Standard Procedure for Microscopic Identification
In microscopic identification, the microscope is used to examine transverse or longitudinal sections, powder, surfaces or
disintegrated tissues of crude drugs and/or of Chinese proprietary medicines mounted on glass slides.
2.1 Sampling
The validity of sampling directly affects the accuracy of identification results; therefore reliable, random procedures of
sampling should be strictly followed. In the description below, “R.S.” refers to reference samples, while “T.S.” refers to
test samples.
R.S. are essential for microscopic identification. The standard R.S. should be determined after strict botanical
taxonomy identification of the original plant. Apart from accurately identifying the original plants of CHM, it should be
noted that the microscopic features of the test object might show variation by growth period and environment.
Therefore the production place, collection time and processing methods should be recorded.
For T.S., origins, production place, specification, grade, packaging style should be noted, and integrity of package,
hygienic level, water trace, extent of mildew and rot and contamination with foreign matter should also be checked and
recorded in detail.
The average quantity of samples should be no less than 3 times what is required for testing. 1/3 of the sample is used
for experimental analysis, 1/3 is used for verification while the remaining 1/3 is retained for at least a year.
2.2 Making Specimen Slides
The quality of specimen slides is critical to microscopic identification; good quality is essential. The method of making
slides should be chosen according to the nature of the material at hand, and the purpose of the investigation.
2.2.1 Transverse Sections
There are four main methods for mounting transverse sections, namely, freehand mounting; glide mounting; cryology
mounting; and paraffin mounting. In all cases, all slides should be clearly labelled with identifying information, e.g.,
name, serial number, origin, date.
(1)Freehand mounting: This method is mainly for making temporary slides. The general procedure for making a
freehand cross-section is as follows: Hold the specimen in the left hand; with a sharp blade in the right hand,
put the blade against the material and slice smoothly from the upper left toward the lower right in a single
motion. Avoid sawing back and forth; keep the specimen and blade lubricated with water.
(2)Glide mounting: This method, using a gliding mounting machine, is suitable for lignum, ligneous roots, stems or
other solid materials. Gliding mounting machine, named as sliding microtome, mainly is composed of
specimen feed, knife holder and specimen orientation. The sturdy construction gives it qualities that ensure
excellent, reproducible sectioning results. The section thickness and knife inclination and declination can be
adjusted.
(3)Cryology mounting: This method is mainly used to make slides of animal tissue, fresh and young herbal tissue.
The steps are as follows: Cut the sample into small pieces (about 1-2 cm in diameter) and embed them with
cryomatrix on a crycasste; freeze them; slice using a machine; mount on glass slides; seal.
(4)Paraffin mounting: This method entails embedding specimens in paraffin, then slicing the block. The steps
include sampling, fixing, dehydration, vitrification, olefin immersion, olefin embedding, slicing, removing the
paraffin, staining with, e.g., safranin and fast green, vitrification after replacing the dyeing solution with a low
to high gradient concentration of ethanol, and finally sealing the mounted specimen with gum arabic or neutral
gum.
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2.2.2 Powders
(1)Pre-treating: The cleaned sample is pulverized. The powder should pass through a No. 4 sieve (average internal
diameter of aperture: 250 ± 9.9 µm) to obtain fine granules.
(2)Mounting: Place the powdered material on the slides. Add 1-3 drops of testing agents; if necessary stir with a
fine pointed needle to distribute testing agent evenly. Add cover slip. Remove any excess liquid that may
exude from under the cover slip by blotting around its edges gently with filter paper.
2.2.3 Fragments
In the case of pieces of tissue, place them on a slide, add wetting agent, tease apart with dissecting needles. Then add a
cover skip.
2.3 Photography
In order to make an accurate and useful record of microscopic features, using the microscope and skills of
photographing are very important. Digital methods of storage make it more and more convenient to save and share
suitable pictures. Setting the functions of exposure time and contrast, crop selection, microscopic measuring must be
mastered.
3. Identification of Chinese Herbal Medicines
3.1. Applications
Microscopic identification has an extensive application in identification of CHMs for determining confused species,
counterfeits and the identify of ingredients of Chinese proprietary medicines. The use of polarized technique and
fluorescence microscope ensures a more accurate and faster identification, which further expands the application. In
recent years, many studies on the authentication of herbal medicine by microscopic techniques have been reported, for
examples, authentication of toxic and potent Chinese Materia Medica [19, 20]; authentication of traditional Tibetan
herbal medicine of Halenia elliptica D. Don and “Meiduoluomi” from eight Aster species [21, 22]. The following are
some examples of how the technique has been successfully used.
(1)Identification of herbal tea—“Ku-Ding-Cha” [23]
Ku-Ding-Cha, a kind of herbal tea, has been widely used in China for a long time to support carciovascular health.
Confusion arises because in different parts of China different plants are used to produce the commercial teas. A
comparative study was made on 24 samples of Ku-Ding-Cha including five standard identified and authenticated plants
and nineteen commercial samples by microscopic techniques (Table 1 and 2, Fig. 1). The results showed that the shapes
of leaf blades, xylem cells, stone cells and calcium oxalate crystals could be used to identify the plants from which the
commercial products were made.
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Table 1 The Microscopic Characteristics of Leaf Transverse Sections (Sketch) and Powder of Five Standard Original Plants
No. Latin Name Location Transverse section Powder
A Ilex kudingcha C.
J. Tseng
Guangxi,
China
B Ilex latifolia
Thumb.
Guangxi,
China
C Ehretia
thyrsiflora (Sieb.
et Zucc.) Nakai
Guangxi,
China
D Clerodendrum
fortunatum L.
HongKong
, China
E Ligustrum
robustum (Roxb.)
Bl.
Yunnan,
China
*A1, A3, B1, B3, B5, C1, C3, D1, D2, E1, E2, E3 were observed under normal light microscope; A2, A4, B2, B4, B6,
C2, C4, E4 were observed under polarized light microscope.
200 µm 100 µm
A1 A2
A3 A4
B1 B2
B3 B4
B5
B6
C1 C2
C3 C4
D1
D2
E1 E2
E3 E4
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Fig. 1 The form of commercial products of Ku-Ding-Cha
A. Sample 1~5; B. Sample 6; C. Sample 7~8; D. Sample 9~14; E. Sample 15; F. Sample 16~17; G. Sample 18~19
Table 2 Key elements of microscopic identification for Ku-Ding-Cha
(Transverse section)
1. No pith in the centre
2. No non-glandular hairs on the upper surface
3. Xylem heart-shaped …………………......................................A) Ilex kudingcha C. J. Tseng
3. Xylem kidney-shaped…………….…………………………...D) Ilex latifolia Thumb.
2. Non-glandular hairs on the upper surface...........................E) Ligustrum robustum (Roxb.) Bl.
1. With pith in the centre
4. No non-glandular hairs on the upper surface........................................................................
...............................................................................C) Ehretia thyrsiflora (Sieb. et Zucc.) Nakai
4. Non-glandular hairs on the upper surface…………………B) Clerodendrum fortunatum L.
(Powder characteristics)
1. Presence of stone cells
2. Stone cells subrounded or subsquare ………………………… A) Ilex kudingcha C. J. Tseng
2. Stone cells irregularly shaped; and presence of prisms of calcium oxalate, polyhedral, rectangular in shape;
15~25µm in diameter………………..……........................... ..D) Ilex latifolia Thumb.
1. No stone cell
3. Presence of calcium oxalate
4. Presence of clusters of calcium oxalate, several arranged in rows, commonly with sharp angles; 30~50µm
in diameter……………………………………………………..C) Ehretia thyrsiflora (Sieb. et Zucc.) Nakai
4. Presence of prisms of calcium oxalate, fine and abundant, consisting in parenchymatous cells; and
presence of non-glandular hairs.…………………………… ..E) Ligustrum robustum (Roxb.) Bl.
3. No calcium oxalate……………………………………… B) Clerodendrum fortunatum L.
(2) Distinguishing the medicinal herb Oldenlandia diffusa from confused species [14]
The herb of Oldenlandia diffusa (Willd.) Roxb. is a well known folk-medicine in China as a component of herb tea.
Two other species of the same genus, namely, O. corymbosa (L.) Lam and O. tenelliflora Bl. had been found sold as
substitutes in commercial herbal markets. In order to find a quick and easy method to distinguish O. diffusa from these
similar species of the same genus, the fluorescence microscope was used to investigate the fluorescence emission
characteristics of the three tissues as compared with light microscopy images of the same material. Based on the shape
of transverse sections of the stem, O. diffusa can be easily differentiated from two similar species of the same genus.
When seen with the routine light microscope, the microscopic characteristics of the stems from O. tenelliflora and O.
corymbosa were very similar; however the two herbs could easily be identified using the fluorescence of the
endodermal cell walls (Fig. 2 and 3). Specifically, the wall of endoderm cells of O. diffusa and O. tenelliflora emit
autofluorescence, while comparable tissue of O. corymbosa does not.
A B C
D E F G
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Fig. 2 Transverse sections of the stems as seen under light microscope (×50)
A. O. diffusa ; B. O. corymbosa; C. O. Tenelliflora
1 mm
A B C
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Fig. 3 Transverse sections of the stems under light microscope and fluorescence microscope (×400)
A. O. diffusa; B. O. corymbosa; C. O. tenelliflora
1. Epidermal Cells; 2. Cortex; 3. Endoderm; 4. Phloem; 5. Xylem; 6. Pith
A-1, B-1, C-1: emission filter through long-pass 397nm; A-2, B-2, C-2: emission filter through long-pass 515 nm
B B-1 B-2
6
5
1
3
2
4
4
5
6
2
1
A A-1 A-2
3
500µm
3
C C-1 C-2
1
5
6
2
4
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(3) Identification of Chinese Proprietary Medicines
Wu Zi Yan Zong Wan, as a classical Chinese Medicine Formula, is used for replenishing the kidney with vital essence.
Both Chinese proprietary medicines and healthcare products prepared according to this formula circulate not only in
China, but also in many other countries such as Japan and the United States. The microscopic identification of Wu Zi
Yan Zong Wan was carried out together with examination of crude samples of its 5 component herbs to ensure the
presence of these constituents in the herbal products (Fig. 4) [24].
Fig. 4 Identification of Wu Zi Yan Zong Wan
1. Original plant 2. Crude drugs 3. Key features of microscopic identification
3.2General Approach to Microscopic Identification of Chinese proprietary medicines
In general, microscopic identification of Chinese proprietary medicines can be classified into two situations. One is
dealing with known constituents, as in the above example; the second is when the constituents are unknown and need to
be identified. In the latter case, identification is much more difficult, because we must know the microscopic features of
virtually all single CHM powders in order to know which one(s) are present. However, apart from the microscope, a
variety of other techniques can also be used in identification. For example, some CHMs in the prescriptions, which do
not have very specific microscopic features, like Borneol (Borneolum syntheticum), can be identified by
microsublimation. Moreover, fragments of powdered crude drugs constituents are usually partly hidden by several other
co-existing crude drugs and additives. In such cases, polariscopic identification is suggested to be the first choice. For
example, polarized microscopy has been applied to identify the ingredients of Zhibao Sanbian Wan, which is in the
form of a large honey pill comprising 38 kinds of powdered crude drugs as a traditional Chinese Medicine commonly
used for tonicity in China and Japan [25].
2
1
3
Key Features of
Wu Zi Yan Zong Wan
Fructus Lycii
Semen Cuscutae Semen Plantaginis
Fructus Rubi
Fructus Schisandrae
2
3
2
3
1
2
1
3
2
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When using microscopy to identify Chinese proprietary medicines, some points should be noted:
(1) Know the form of medication, and be familiar with the constituents of prescription;
(2) Eliminate overlapped interference; and identify specific features;
(3) Master the standard operations;
(4) Strive for accuracy.
4. Use of the Microscope in Quality Evaluation of CHMs
As CHMs are increasingly used worldwide, evaluating the quality and ensuring the correct identify of CHMs has
become an internationally critical issue. Confused species or inferior quality of herbal materials can, at the least, degrade
the curative effects of herbal medicines or, at the worst, induce poisoning. Microscopic identification is an effective means
for identifying CHMs plant material. However, authentication of CHM includes both identifying the crude plant product
and evaluating its pharmaceutical quality. Today, quality evaluation mostly depends on complex and expensive
instruments operated by professional technicians, and is recorded in terms of active metabolites. If biologically active
components can be correlated with microscopic characteristics, then evaluating the quality of CHM becomes much
more practical and can become widespread, with many beneficial results.
It is well known that the metabolites-- including the pharmacologically active components of CHMs-- distributed in
plant tissues of microscopic characteristics have a specific, predictable relationship with quality of CHMs. That is to say,
analysis of chemicals in plant tissues will assist to evaluate the quality of CHM by quantification of plant tissue which
contain the active components. The study on the analysis of chemicals in plant tissues has been reported. The technique of
matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry (MALDI-TOF-MS) has been applied for
histochemical analysis in our previous studies. The results demonstrated that the plant tissues have a close correlation
with chemical components. For example, the results of in vivo analysis and spatial profiling of chemicals in stem tissue
of Sinomenium acutum (Thunb) Rehd. et Wils by MALDI-TOF-MS indicated that the chemicals (+)-menisperine,
stepharanine, sinomenine and sinomendine are mainly distributed in xylem while magnoflorine is found in pith [26]. In
another of our previous studies, it was found that the content of sinomenine in the plants of large size (stem diameter >3
cm) was much higher than those of small size (stem diameter <1 cm) [27]. Both the two previous studies showed that
the active chemicals were distributed in the xylem tissue of the stem of S. acutum. Therefore, the microscopic
characteristic of the stem tissue of S. acutum most valuable for determination of pharmaceutical quality is the quantity
of vessels. Additionally, the alkaloid profiling in plant tissue of the root of Aconitum carmichaeli Debx. as well as crude
and processed Strychnos nux-vomica seeds has been successfully analyzed by MALDI-TOF-MS technique [28, 29].
Laser microdissection (LMD), which can separate the different tissues in transverse sections, is proving to be very
useful in the authentication of herbal products. For example, LMD combined with cryogenic nuclear magnetic
resonance (NMR) and mass spectrometry has been applied to analyse the chemicals in stone cells of Norway spruce
(Picea abies) [30]. LMD also has been used to separate the secretory cavities from leaves of Dilatris pillansii Barker.
Then cryogenic 1H NMR spectroscopy and HPLC analysis were used to analyze the microdissected samples; this
process revealed two novel and one known natural products in secretory tissues [31]. The identification of secondary
plant metabolites from a single laser-microdissected population of plant cells combined with sensitive analytical
techniques offers a new way to determine the chemical profiles of specific plant cell types with a high degree of
precision. In other word, using LMD to localize natural products in specific plant cell populations makes it possible to
correlate microscopic characteristics and CHM pharmaceutical quality.
5. Conclusion
In conclusion, microscopic identification is a reliable, efficient and effective method for the authentication of herbal
medicines in general and Chinese herbal medicines in particular. However, authentication of CHM includes both
identifying the crude plant product and evaluating its pharmaceutical quality. As microscope technology advances, with
corresponding advances in analytical chemistry, it is becoming feasible to also evaluate the quality of CHMs from
microscopic examination.
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