|Year : 2011 | Volume
| Issue : 3 | Page : 402-407
Effect of Shodhana (processing) on Kupeelu (Strychnos nux-vomica Linn.) with special reference to strychnine and brucine content
Swarnendu Mitra1, VJ Shukla2, Rabinarayan Acharya3
1 Ph.D. Scholar, Department of Dravyaguna, Institute for Postgraduate Teaching and Research in Ayurveda, Gujarat Ayurved University, Jamnagar, India
2 Head, Pharmaceutical Chemistry Laboratory, Institute for Postgraduate Teaching and Research in Ayurveda, Gujarat Ayurved University, Jamnagar, India
3 Associate Professor, Department of Dravyaguna, Institute for Postgraduate Teaching and Research in Ayurveda, Gujarat Ayurved University, Jamnagar, India
|Date of Web Publication||17-Mar-2012|
Associate Professor, Department of Dravyaguna, I.P.G.T. & R.A., G.A.U., Jamnagar, Gujarat
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Kupeelu (Strychnos nux-vomica Linn.) commonly known as nux vomica is a poisonous plant used extensively in various ayurvedic formulations, with great therapeutic significance. Ayurveda recommended the administration of Kupeelu only after purification in different media like cow's urine (Go mutra), cow's milk (Go dugdha), cow's ghee (Go ghrita), Kanji (sour gruel), and so on. Apart from the classical methods some other methods are also adopted by the traditional practitioners using castor oil (Eranda taila), ginger juice (Ardraka swarasa), in the purification of Kupeelu seeds. In the present study an attempt has been made to purify the seeds by performing two different methods (one classical and another traditional) using Kanji and Ardraka swarasa as Shodhana media. This study reveals that both the methods studied reduce the strychnine and brucine contents in comparison to the raw seeds as determined by high performance thin layer chromatography (HPTLC). After purification in Kanji and Ardraka swarasa, the strychnine content was reduced by 39.25% and 67.82%, respectively, and the brucine content in the purified seeds was also found to have decreased by 17.60% and 40.06%, in comparison to the raw seeds.
Keywords: Ardraka swarasa, brucine, kanji, kupeelu, shodhana, strychnine
|How to cite this article:|
Mitra S, Shukla V J, Acharya R. Effect of Shodhana (processing) on Kupeelu (Strychnos nux-vomica Linn.) with special reference to strychnine and brucine content. AYU 2011;32:402-7
|How to cite this URL:|
Mitra S, Shukla V J, Acharya R. Effect of Shodhana (processing) on Kupeelu (Strychnos nux-vomica Linn.) with special reference to strychnine and brucine content. AYU [serial online] 2011 [cited 2020 Oct 26];32:402-7. Available from: https://www.ayujournal.org/text.asp?2011/32/3/402/93923
| Introduction|| |
There are many poisonous plants reported in the ancient scriptures of Ayurveda, which are still in practice widely, to combat a number of diseases after proper Shodhana (purification/detoxification).  Kupeelu (Strychnos nux-vomica Linn.) is such a plant described under the 'Upavisa Vargas' (semi poisonous group)  and its seeds have been used successfully in cure of many diseases after proper Shodhana.  Nux vomica was introduced in Europe in the sixteenth century, but was not used much in medicine, being chiefly employed to poison dogs, cats, crows, and etc.  It is cited in the treatises of Ayurveda that the 'Visha' (poison) becomes 'Amrita' (nectar) after logical administration  and the ancient physicians of Ayurveda successfully used this drug in a number of diseases after proper purification in some specific media. Either S. nux- vomica or its alkaloids have been reported for their analgesic, anti-inflammatory,  anti-oxidant,  anti-tumor  , anti-snake venom,  anti-diarrheal,  and hepatoprotective  activities in different modern literature. Although 16 alkaloids have been separated and identified from crude nux vomica, 80% of them are strychnine and brucine and their derivatives such as isostrychnine and brucine N-oxide.  The major chemical constituents of nux vomica, (strychnine and brucine) have been reported for their adverse effects. 
Specific Shodhana (purification) procedures have been adopted for the purification of nux vomica seeds and these methods are either mentioned in the classics of Ayurveda or practiced traditionally. ,,, The concept of Shodhana (purification) in Ayurveda is not only a process of purification / detoxification, but also a process to enhance the potency and efficacy of the drug.  For instance it is reported that aconite (Vatsanabha) purified by cow's urine is converted to a cardiac stimulant, whereas, raw aconite is a cardiac depressant.  Purified Kupeelu is also claimed to be a potent drug in countering old age problems and specially recommended during senility as a Rasayana (antioxidant).  Different techniques ,,,, have been used for the analysis and quantification of strychnine and brucine in raw and processed seeds. Few reports are also present, which explore various methods of purification of nux vomica seeds as per Chinese,  Unani,  and Ayurveda  systems of medicine. However, the methods of purification and analytical techniques are different from those considered under the present study. The purpose of the study is to evaluate the role of purification in the quantitative reduction of toxic alkaloids of Kupeelu seeds by the high performance thin layer chromatography (HPTLC) technique.
| Materials and Methods|| |
Collection of drugs
Fully matured Kupeelu (Strychnos nux-vomica Linn.) fruits were collected from Bankura district, West Bengal, in India, during the month of December, and were botanically authenticated by pharmacognosists. The sample specimen were kept in the museum for future reference. The seeds were taken out from the fruit pulp, thoroughly washed with tap water, and shade dried.
Preparation of media
Kanji was freshly prepared following the method mentioned in the Ayurvedic Formulary of India  and fresh Ardraka (ginger) was procured from the local market. Fresh juice from the Ardraka was extracted in the early morning and used as the media for purification.
Selection of seeds
The dried seeds were first dropped in a beaker containing water. The seeds that floated on the surface of water or found broken, black in color, were rejected and the seeds that settled at the bottom of the beaker were selected for purification after drying in air  and were considered as raw drug (KR).
Equipments for Shodhana (Purification)
A China clay jar having a capacity of 10 L, China clay vessel (16 cm radius of mouth × 12 cm depth) having capacity of 2 L, glass rod (length 28 cm), cotton thread 30 cm, measuring mug (capacity of 1 L), muslin cloth (45 cm × 45 cm), stainless steel spatula (length 30 cm), digital weighing machine, and induction heater.
Equipments for high performance thin layer chromatography
A CAMAG (Switzerland) high performance thin layer chromatography (HPTLC) system equipped with a sample applicator Linomat V sample applicator was used for the application of samples. CAMAG TLC Scanner 3, Reprostar, and Wincats 4.02 were used for scanning the plates. A CAMAG twin through a glass chamber was used for developing the plates.
Pure strychnine and brucine were obtained from Sigma Aldrich, USA, and precoated silica gel 60 F 254 TLC aluminum plates (10 × 10 cm, 0.2 mm thick), AR grade toluene, ethyl acetate, diethyl amine, methanol and chloroform were obtained from M / S Merck Ltd. Mumbai, India.
Methods of purification of Kupeelu (Strychnos nux-vomica Linn.) in different media
Each purification method was carried out in three batches, by using two different media as per classical and traditional processes, as mentioned herewith.
I. Purification with Kanji
Seeds (100 g) were processed by dipping in 1L Kanji (pH: 3.4) for three consecutive days in a china clay vessel.  The media was changed every 24 hours. On the fourth day, the seeds were taken out and washed with lukewarm water. The outer seed coat and embryo were removed and cotyledons were dried and pulverized. The pulverized material was kept in an air tight glass container and marked as 'KKJ powder' for further use.
II. Purification using Ardraka swarasa (freshly extracted ginger juice) as media
Seeds (100 g), were soaked in 1L of Ardraka swarasa for 20 days in a china clay vessel.  Every day the seeds were stirred well with a glass rod. On the twenty-first day, the seeds were taken out, washed with lukewarm water, the outer seed coat and embryo were removed, cotyledons were dried and pulverized. The pulverized materials were kept in an air tight glass container and marked as 'KAS powder' for further use.
High performance thin layer chromatography method for estimation of strychnine and brucine
Preparation of standard strychnine and brucine solution
Strychnine standard (10 mg) and brucine standard (10 mg) were accurately weighed and dissolved in methanol in two standard flasks and the final volumes were adjusted to 10 ml with methanol. (1 μg / μl)
Calibration curve for strychnine and brucine
The standard solutions corresponding to 2 μg to 6 μg of standard strychnine and brucine were applied on TLC plates (10 cm× 10 cm), precoated with silica gel as 6 mm bands by using CAMAG Linomat IV sample applicator. The plate was developed in a solvent system of Toluene : Ethyl acetate : Diethyl amine (7 : 2 : 1, v / v) in a CAMAG twin through a chamber up to a distance of 7.5 cm at a temperature of 30 ± 2°C. The plates were air dried and scanned at a wavelength of 254 nm using the CAMAG TLC scanner and CATS V 4.06 software. The peak area of strychnine and brucine were recorded for each concentration. The calibration curves of strychnine and brucine were obtained by plotting the graphs of the peak areas versus the concentrations of strychnine and brucine.
Preparation of sample solutions for estimation of strychnine and brucine
Both the purified samples (2 g each) were defatted individually with petroleum ether. The defatted samples were then mixed with 10% ammonia and finally extracted with 25 ml methanol for one hour, under reflux. The methanol extracts were filtered and concentrated to 5 ml and used as test solutions. Each test solution of 5 μl was spotted along with 2 to 6 μl standard solutions of strychnine and brucine. The plates were developed in a mobile phase of Toluene : Ethyl acetate : Diethyl amine (7 : 2 : 1, v / v) and scanned at 254 nm for strychnine and brucine. Peak areas were noted and the quantities of strychnine and brucine were calculated by comparing the areas of the standard solutions from calibration curve.
| Results and Discussion|| |
The preliminary phytochemical investigation showed the presence of alkaloids, tannins, carbohydrates, proteins, fixed oils in methanolic extracts of raw and purified seeds. The glycoside loganin, which was present in raw seeds was found to be absent in the purified seeds. The presence of strychnine and brucine was confirmed by comparing the Rf values with those of the standard markers by HPTLC.
It was also observed that 54.20 and 66.30% of purified Kupeelu was obtained after purification in Kanji and Ardraka swarasa, respectively [Table 1] and [Table 2]. The moisture content in Kupeelu was increased after purification with Kanji, but decreased when the seeds were processed in Ardraka swarasa [Table 3]. The water-soluble and alcohol-soluble extractive values were decreased in both the samples after purification [Table 3]. Water and alcohol-soluble extractive values in Kanji purified seeds were comparatively less than those in the Ardraka swarasa purified samples. Therefore, better extraction of alkaloids, along with other chemical constituents, took place when the raw samples were kept in Kanji. However, reduction in the alkaloid content like strychnine and brucine was only observed when the samples were processed in Ardraka swarasa. Therefore, a hypothesis can be drawn that as far as reduction in concentrations of toxic alkaloids are concerned either by extraction or by transformation into another form Ardraka swarasa may be a better media than Kanji.
|Table 1: Effect of Shodhana (purification) by Kanji on the yield of the final products and organoleptic characters|
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|Table 2: Effect of Shodhana (purification) by Ardraka swarasa on the yield of the final products and organoleptic characters|
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Kanji (pH 3.4) being acidic in nature may facilitate the extraction of alkaloids like strychnine and brucine, along with other chemical constituents from nux vomica seeds. Thus, it may be assumed that Kanji is a better extraction media than Ardraka swarasa.
In the HPTLC chromatogram, the UV spectrum of standard strychnine (R f 0.54) at 254 nm and standard brucine (R f 0.34) [Figure 1] and [Figure 2], and the peak areas of strychnine and brucine in all the samples are exposed [Figure 3], [Figure 4] and [Figure 5]. Calibration curves of strychnine and brucine were prepared by plotting concentrations of strychnine and brucine in the range of 2-6 μg / spot versus average area of the peak. The responses for concentrations of standard strychnine and brucine were found to be linear [Figure 6] and [Figure 7]. The amount of strychnine and brucine in the raw and purified samples were computed from the calibration curves, which suggested that the highest reduction of strychnine and brucine was found in the Ardraka swarasa purified samples [Table 4]. It might be due to the fact that prolonged contact of the seeds with Ardraka swarasa not only helped to diffuse out some quantity of the alkaloids from the seeds, but also some amount of strychnine and brucine might have been converted into less toxic derivatives like isostrychnine, isobrucine, strychnine N-oxide, brucine N-oxide, and so on.
|Figure 3: HPTLC of raw Kupeelu showing peak areas of strychnine and brucine|
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|Figure 4: HPTLC of Kupeelu purified by Kanji showing peak areas of strychnine and brucine|
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|Figure 5: PHPTLC of Kupeelu purified by Ardraka swarasa showing peak areas of strychnine and brucine|
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|Table 4: Results of estimation of strychnine and brucine in raw and purified samples of Kupeelu by HPTLC|
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| Conclusion|| |
From this study it may be concluded that for purification of Kupeelu, Kanji is a better extraction media than Ardraka swarasa.
Seeds of Kupeelu purified by Ardraka swarasa may be regarded as better method of purification as far as toxic alkaloids are concerned. These findings strongly confirm the claims of the traditional practitioners of Ayurveda that the Shodhana (purification) process of Kupeelu by Ardraka swarasa successfully reduces the toxic elements of the drug and this process may be practiced routinely in future.
| Acknowledgment|| |
The authors are very thankful to the Director of I.P.G.T & R.A, G.A.U, Jamnagar, India, for providing all the necessary facilities for carrying out this study. The authors are also thankful to Dr. Galib and Dr. B.R. Patel, Asst. Prof., I.P.G.T and R.A, G.A.U, Jamnagar, for their technical help.
| References|| |
|1.||Anonymous. Ayurved Sara Samgraha. 13 th ed. Kolkata: Sri Baidyanath Ayurveda Bhawan Ltd; 1985. p. 237-40. |
|2.||Sharma SN, Shastri KN. Rasa Tarangini. 11 th ed. New Delhi: Motilal Banarasidas Publication; 2000. P. 163-4. |
|3.||Gogte VM. Ayurvedic pharmacology and therapeutic uses of medicinal plants. 1 st ed. Mumbai: Bharatiya Vidya Bhavan; 2000. P. 345-7. |
|4.||WilliamsEvans C. Pharmacognosy. 16 th ed. United Kingdom: Elsevier Limited; 2009. p. 399. |
|5.||Agnivesa, Charaka, Dridhabala, Charaka Samhita, Sutra Sthana, 1/126, edited by Sharma R. K, Das Bhagwan. Charaka Samhita, Text with English translation and critical exposition based on Cakrapani Dutta's Ayurveda Dipika, Chowkhamba Sanskrit Series Office; Varanasi, 2008. p.59. |
|6.||Yin W, Wang TS, Yin FZ, Cai BC. Analgesic and anti-inflammatory properties of brucine and brucine N-oxide extracted from seeds of Strychnosnux-vomica. J Ethnopharmacol 2003;88:205-14. |
|7.||Tripathi YB, Chaurasia S. Effect of Strychnosnux vomica alcohol extract on lipid peroxidation in rat liver. Pharm Biol 1996;34:295-9. |
|8.||Deng XK, Yin W, Li WD, Yin FZ, Lu XY, Zhang XC, et al.The anti-tumor effects of alkaloids from the seeds of Strychnosnux-vomica on HepG2 cells and its possible mechanism.J Ethnopharmacol2006;106:179-86. Available from: http://www.ncbi.nlm.nih.gov/pubmed/16442763 [Last cited on 2010 Apr21]. |
|9.||Chatterjee I, Chakravarty AK, Gomes A. Antisnake venom activity of ethanolic seed extract of Strychnosnux vomica Linn.Indian J Exp Biol 2004;42:468-75. |
|10.||Shoba FG, Thomas M. Study of antidiarrhoeal activity of four medicinal plants in castor-oil induced diarrhea.JEthnopharmacol 2001;76:73-6. Available from: http://www.ncbi.nlm.nih.nov/pubmed/11378284 [Last cited on 2010 Jul 02]. |
|11.||Gopalkrishna SV, Lakshmi Narasu M, Ramachandra SS. Hepatoprotective activity of detoxified seeds of nux vomica against CCl 4 induced hepatic injury in albino rats . Pharmacologyonline 2010;1:803-15. |
|12.||Cai BC, Hattori M, Namba T. Processing of nux vomica. II. Changes in alkaloid composition of the seeds of Strychnosnux-vomica on traditional drug-processing. Chem Pharm Bull 1990;38:1295-8.Available from: http://www.ncbi.nlm.nih.nov/pubmed/2393954 [Last cited on 2010Jun3]. |
|13.||Nadkarni KM. Indian materia medica. Vol 1. 13 th ed. Mumbai: Popular Prakashan; 1976. p. 1175-11. |
|14.||Sharma SN, Shastri KN. Rasa Tarangini.11thed. NewDelhi: MotilalBanarasidas Publication; 2000. |
|15.||TrivediKrishnaprasad., editor. Dhanwantari Banausadhi Visesanka. Vol. 2. Vijaygara: Dhanwantari Karyalaya;1963. p. 270. |
|16.||A. Hafiz Haji Musa Bhadkodravi Sa., editor. Adu Anjirna Guno-Vishesatao. Gujarat: Haji Md. Rafiq Musa Patel Publication; 2000. p. 20-21. |
|17.||Trikamji. Acharya Jadavji, editor. Siddhayog Samgraha, 13 th ed. Allahabad: Shree Baidyanath Ayurved Bhavan Ltd; 2008. p. 163. |
|18.||Shastri JL. Dravyaguna Vijnana. 1 st ed. Varanasi: Choukhamba Orientalia; 2009. p. 320. |
|19.||Singh LB, Singh RS, Bose R, Sen SP. Studies on the pharmacological action of Aconite in the form used in Indian Medicine. Bull Med Ethnobot Res 1985;6:115-23. |
|20.||Pandey G. Anti-Aging Herbal Drugs of India. 1 st ed. Delhi: Sri Satguru Publication; 2002. p. 248. |
|21.||Hagi G, Hatami A, Safaei A. Hydrophilic-interaction chromatography with UV detection for analysis of strychnine and brucine in the crude seeds of strychnos nux vomica and their processed products. Chromatographia 2010;71:327-30. |
|22.||Choi YH, Sohn YM, Kim CY, Oh KY, Kim J. Analysis of strychnine from detoxified Strychnosnux-vomica [corrected] seeds using liquid chromatography-electrospray mass spectrometry. J Ethnopharmacol 2003;93:109-12. Available from: http://www.ncbi.nlm.nih.gov/ pubmed/15182914 [Last cited on 2010 Jun 01]. |
|23.||Kaye S, Hoff Ebbe C. Identification and determination of strychnine by Ultraviolet Spectrophotometry.J CrimLawCriminolPolice Sci1952;43:246-9. Available from: http://www.jstor.org/stable/1139284 [Last cited on 2010 Oct 04]. |
|24.||Duverneuil C, Grandmaison G, Mazancourt P, Alvarez J. Liquid chromatographyl photodiode array detection for determination of strychnine in blood: A fatal case report.2004;141:17-21. Available from: http://www.fsijournal.org/article/s0379-0738(03)00545-0/ abstract [Last cited 2010 Oct 04]. |
|25.||Li Y, He X, Qi S, Gao W, Chen X, Hu Z. Separation and determination of strychnine and brucine in Strychnosnux-vomica L. and its preparation by nonaqueous capillary electrophoresis. 2006;41:400-7. Available from: http://www.sciencedirect.com/science? [Last cited on 2010 Oct 04]. |
|26.||Cai B, Nagasawa T, Kadota S, Hattori M, Namba T, Kuraishi Y. Processing of nux vomica. VII. Antinociceptive effects of crude alkaloids from the processed and unprocessed seeds of Strychnosnux-vomica in mice. China. Biol Pharm Bull 1996;19:127-31. Available from: http://www.ncbi.nlm.nih.gov/pubmed/8820924 [Last cited on 2010 June 03]. |
|27.||Akbar S, Khan SA, Masood A, Iqbal M. Use of strychnosnux vomica (Azraqi) seeds in unani system of medicine: Role of detoxification. Afr J Tradit Complement Altern Med 2010;7:286-90. |
|28.||Mehta N, Prajapati PK, Chadhuary AK. Role of milk in Shodhana (detoxification) with special reference to Nux-vomica. Aryavaidyan 2007;20:100-4. |
|29.||Anonymous. The Ayurvedic Formulary of India. Vol. 2. 1 st ed. New Delhi: Govt. of India; 2007. p. 123. |
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6], [Figure 7]
[Table 1], [Table 2], [Table 3], [Table 4]