Year : 2010 | Volume
: 1 | Issue : 1 | Page : 41--46
Building bridges between Ayurveda and Modern Science
Department of Kaya Chikitsa, State Ayurvedic College and Hospital, Tulsi Das Marg, Lucknow - 4, Department of Holistic Medicine, BMCRC, Vatsala Hospital, Tulsi Das Marg, Lucknow, India
Vatsala Hospital, Tulsi Das Marg, Lucknow - 226 004
The recent decade has witnessed many landmark observations, which have added to the scientific credentials of Ayurveda.It is however believed that instead of a retrospective approach of looking into the Ayurveda through the scientific reappraisals, a prospective approach through primary understanding of Ayurveda followed by a search into scientific linkage would be more appealing. This article brings the simplified yet scientific decoding of the core concepts of Ayurveda that form the framework of this ancient science of health.
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Rastogi S. Building bridges between Ayurveda and Modern Science.Int J Ayurveda Res 2010;1:41-46
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Rastogi S. Building bridges between Ayurveda and Modern Science. Int J Ayurveda Res [serial online] 2010 [cited 2015 Jan 29 ];1:41-46
Available from: http://www.ijaronline.com/text.asp?2010/1/1/41/59943
The 21st century has marked the beginning of a new era, receptive to eastern healthcare philosophy through positive attitudes.  Epitomizing eastern philosophy for its concern to values related to health, Ayurveda is by and large considered to showcase traditional health care. Before the recent upsurge of traditional medicine in a global perspective, Ayurveda was persistently criticized for its ambiguity and philosophical tenets incomprehensible to occidental mind. This perception has led to disinterest in Ayurveda in the western world, which eventually and unfortunately has led the world to be deprived of many plausible advantages of traditional healthcare supportive to a total quality life (TQL). ,,,
Contrary to the global scene, Ayurvedic schools in India consistently urge for scientific rooting of Ayurvedic principles. A connotation of linking science and Ayurveda is well perceived by Ayurvedic physicians in India, and schools like Banaras Hindu University (BHU) have pioneered this thought. What prevented this thought from becoming a reality? A poor scientific appraisal of Ayurvedic principles among Indian scientific community eventually resulted in a poor interdisciplinary collaboration between science and Ayurveda. This subsequently led to a premature demise of this thought until it has been resurrected recently with stronger evidence to rely on. Thinking of effective utilization of Ayurveda through a better understanding of its fundamentals is the recent realization. Fortunately, this realization has given rise to a spurt of an impulsive and argumentative pro-Ayurvedic generation as its eventuality.  Global dissemination of Ayurveda required its scientific presentation besides minimization of its semantic barriers helping it to become comprehensible to the people exogenous to it. Fortunately, a few among the new genre have prompted to sense this reality and stand up as intermediaries, speaking in a mutually understandable language and retrieving the link of Ayurveda to science while keeping its original flavor intact. ,
Origin of Life: from Ayurveda to theory of biopoiesis
How did life evolve on Earth? This is the question stirring the human mind all through the ages. Initial proposals of spontaneous generation soon transformed into omne vivum ex ovo (every living thing comes from a pre-existing living thing) before arriving finally at theory of biopoiesis. A biopoiesis theory ultimately proposed for a three-step transition between non-livings to living earth. These transitional stages are postulated as:
1. Origin of biological monomers; 2. Origin of biological polymers and 3. Evolution of cells from polymers. 
Revisiting the recent understanding of origin of life through an Ayurvedic viewpoint surprisingly explores a remarkable clarity and similarity of postulates.
Elaborating its postulates about origin of life, Ayurveda, fundamentally proposes a few dictums, which are equally re-phrasable to their modern contexts of origin of life. These dictums are:
1. Nasato vidyate bhavo, na bhavo vidyate satam (non-existence cannot give rise to existence) [INSIDE:1] as an Ayurvedic version to omne vivum ex ovo (every living thing comes from a pre-existing living thing). This dictum argues for the omnipresence of formative substances of life since eternity.
2. Origin of life process began from Avyakta (invisible) and reached to Vyakta (visible) stage after passing through number of intermediaries.
Ayurveda proposes for an omnipresence of basic building blocks of life in the universe suggesting that beginning of synthesis is subject to the availability of optimal conditions. This justifies the life process to begin only a few billion years ago despite availability of the basic materials since eternity. Primitive earth was proposed to be characterized by Sattva, Rajas and Tamas (Triguna) symbolizing the physical properties prevalent to the primitive earth. Sattva, the foremost of Triguna, symbolizes the energy required for creation, Rajas, the second of Triguna symbolizes the particle movements and Tamas finally symbolizes inert material having a capacity to convert into new forms under the constant influence of Sattva and Rajas.
It is interesting to hypothesize a resemblance between Sattva, Rajas and Tamas to that of conditions available to primitive earth that acted decisively to begin the actual process of origin of life [Table 1].
Ayurveda argues for life beginning from invisible components. While passing through many intermediate stages these components reach a physically visible stage called as Mahabhuta (maha = big, bhuta = first form of existence). Mahabhuta are proposed to be the consolidation products of invisible formative units or Tanmatra (smallest possible component of Mahabhuta having similar properties, but invisible). Eventually, a Mahabhuta in turn happens to be a consolidation and combination product of various Tanmatra in a predetermined differential order. It is interesting to note that only five types of Tanmatra and consequently five Mahabhuta are described in Ayurveda. This numerological agreement upon the number of Mahabhuta is in accordance with the physically perceptible forms of matter, its absence and also with the state of energy acting in transition. The five Mahabhuta are also linked to the five sense organs as means of their perception [Table 2]. It is further interesting to note that Ayurveda has described the element of Agni (fire) as a Mahabhuta long before the proposition of energy and matter transitions by Einstein.
Modern science supports the proposition that five Tanmatra are the progenitors of their visible counterparts by describing basic formative particles (electron, proton and neutron- which could be the tanmatras) combining in different proportions and forming atoms, elements and compounds. Ayurveda says Sarvam dravyam hi panchabhauticam [INSIDE:2] or every substance in the universe is composed of five basic elements only. This further shows a conceptual similarity between modern science and Ayurveda with reference to the idea of substance generation.
The theory of Tridosha (three doshas namely Vata, Pitta and Kapha) fundamentally brings Mahabhuta theory into a practical, usable and understandable format for its application to the cause of human health. It forms the basis of Ayurvedic physiology and subsequently paves the way to its clinical application. Tridosha symbolizes the physico-biological properties of compounds made through a differential combination of Mahabhutas. Tridosha, therefore, represents the physiological functioning of a living body, which eventually is the property of its component material. Ayurvedic idea of disease and health is conceived around this concept by identifying a balance of Tridosha and eventually that of the Panchamahabhuta representing health. An imbalance of Mahabhuta, therefore leads to qualitative disturbance of physiological functions subsequently identified as a disharmony of dosha causing a disease.
Panchamahabhuta are also held responsible for the creation of nonliving things in the same way as they are to the living ones. Sarvam dravyam hi panchabhauticam [INSIDE:3] is this generalization of Ayurveda about material composition, which lays the foundation to its understanding that every substance on earth has a potential as medicine (Nanaushadhibhutam jagat kinchit).
Prakriti: The proto type
Prakriti represents another interesting facet of basic principles of Ayurveda having great impacton predictive medicine. Prakriti is described to be formed of characteristic physiological, physical and mental features of an individual, and is classified into subgroups depending on specific dosha predominance. Etymologically Prakriti (pra = primary or first, kriti = formation or creation) stands for the prototype representing the basic formative distinction in a given individual. For practical purposes, it can be characterized by the observation of dosha activity in the body and eventually to the Panchamahabhuta status in the body. Tracing the origin of Prakriti to its Panchbhautic ancestry one is able to identify certain pattern of combinations of the mahabhutas. Ayurveda identifies these patterns of Prakriti as subgroups with the predominance of one or more dosha in an individual case. Seven subgroups of Prakriti are possible representing a differential combination or equi-presence of each one of the Tridoshas, namely Vata, Pitta and Kapha.
Knowledge of the basic prakriti of a person is useful tostay in a state of positive health and prevent disease. Recent research has tried to identify the inheritance possibilities of human Prakriti by observing positive correlations between specific alleles and Prakriti sub-types.  An advancement to this correlation is further made by identification of biochemical correlates and whole genome expression to the various Prakriti types.  A correlation between CYP2C19 genotype and Prakriti with fast and slow metabolic features have been attempted recently.  Features representing Prakriti subtypes as per their dosha specification have also been attempted for their statistical validation. 
Tridosha: Modus operandi of an open system
Tridosha is the physiological basis around which practical Ayurveda revolves. The theory of Tridosha is developed primarily as a tool to quantify the pathogenesis and consequently to quantify the need of healthcare interventions in any given condition. As it is practically difficult to assess the status of ahabhutas whether in a state of balance or not to predict healthy state or diseased state) assessment of the status of the tridoshas has become come the preferred way of decision-making in therapeutics in Ayurveda. Three basic functions operating through a constant interplay between the environment and the individual are thought to be required to maintain the integrity of a living system. Hankey's (2007) proposal of input-output, throughput and storage as three basic functions of an open system resemble functions of Vata, Pitta and Kapha, respectively, as proposed in Ayurveda.  The functions of input-output, throughput and storage or incidentally of Vata, Pitta and Kapha are primary requisites for the existence of any living system. In turn, these are considered to be the manifestation of compositional complexity of a person. Consequently, a Mahabhautic root to the Vata, Pitta and Kapha is identified as described in [Table 3]. By observing the function of their representative dosha, a deficit or the excess of the Mahabhuta can be identified as the cause behind the state of sickness or health.
Rasa: A tool to identify and quantify appropriate measure of health maintenance.
Pathology, as proposed in Ayurveda, is the manifestation of Mahabhautic imbalance leading to physiological disturbances of Vata, Pitta or Kapha resulting intheir disequilibrium. Identification of a dosha disharmony in terms of its deficit, excess or qualitative disturbance and consequently of Mahabhuta, and then its re-correction to its original state is requited to restore health.
Through the nanaushadhibhutam jagat kinchit [INSIDE:4] dictum, Ayurveda identifies every object in the universe as a potential medicine based upon its Panchbhautic composition. The panchabhautic characteristic of medicinal materials used in Ayurveda (herbs and minerals) cannot be identified using the conventional Tridosha theory. Thus, other perceptible, yet scientific and representative parameters have been described for identification of their elemental predominance. Rasa (taste) is conceived as a perceptible and representative attribute of a substance which reflects reproducibly and accurately its elemental composition. Ayurveda has described six rasas and has proposed a clear correlation of Rasa to the elemental predominance in substances [Table 4]. 
The idea of Rasa as an attribute representing pharmacological properties of a substance has recently been brought under a scientific scrutiny.  Ibuprofen and Oleocanthal are found to have similar pharmacological action despite obvious differences in their chemical structures. These substances produce a strong stinging sensation in the throat, and irrespective of their structural differences are found to have COX-1 and COX -2 inhibiting properties.  Their similarity of action is attributed to their taste and not to their chemical structure. Rasa, therefore, acts as an intermediary between physician and patient for a logical identification of right medicine in individual clinical conditions where a diagnosis in terms of elemental imbalance is made.
Besides Rasa, Ayurveda further identifies a few more attributes to determine pharmacological property of a substance. These include Guna (property), Virya (potency), Vipaka (post-digestion property) and Prabhava (special effect) and all these are needed to fully understand the complete pharmacological effect of a substance. The Rasa and corresponding attributes of a substance, independently or in coherence are used in Ayurveda for identifying the pharmacological effect and subsequently for the clinical usage of a medicine. Different Rasa have also been described to produce variable effects on functions of dosha . This makes the consideration of dosha and rasa of a medicine very crucial in the practice Ayurvedic medicine [Table 5].
Science and Ayurveda: Rediscovering the lost keys
The 21st century began with a few landmark observations that helped decisively to rediscover the lost links between modern Science and Ayurveda. This period has also proposed certain new models to comprehend Ayurvedic fundamental tenetson grounds acceptable to the Western world.  The evolved and explicit human physiology and behavioral science have been described to have their seeds in the philosophy of Ayurveda.  The identification of a genomic link to the theory of Prakriti led to a search for possible classification of people on their Prakriti based on theirgenetic make up.  These studies could eventually lead to a personalization of medical practice on the basis of prakriti as is conceived in Ayurveda. 
Reappraisal of Ayurvedic phytochemistry gives a strong support to the Ayurvedic fundamental constructs about the taste (Rasa), after taste (Vipaka), special effects (Prabhava) and pharmacological impacts (Guna) of medicinal plants.  Ayurvedic pharmaceutics are receiving a new thrust through a reappraisal of Bhasma preparations (preparations, where herbs, minerals and metals are incinerated to ash under supervised conditions) as novel nano-technological applications. Typical features of Ayurvedic Bhasma have been recently demonstrated through transmission electron microscopy and atomic force microscopy.  A further study has shown Swarna (Gold) bhasma principally constituted of globular gold particle of 56-57 nm. Interestingly, the same study also revealed Swarna bhasma to be devoid of any other heavy metal or organic material by its screening through Atomic Absorption Spectroscopy (AAS) and Infrared Spectroscopy (IS).  This study also put to rest concerns about the presence of heavy metals in ayurvedic preparations which otherwise clouds the popular use of Ayurvedic medicines abroad.  The nano-particle size of ayurvedic Bhasmas, has been confirmed in another study,  where it is proposed that the nano-particles are responsible for its fast and targeted action. These nano-particles are proposed to be delivered to the target through rapid cellular internalization. Subsequent actions upon DNA/RNA molecule and protein synthesis within the cell are further hypothesized as possible mechanisms for rapid onset of therapeutic actions of Bhasma preparations. Pyrgiotakis (2007), with the help of Raman spectroscopy, has demonstrated the effect of Yashada (Zinc) bhasma on intracellular DNA and proteins of the treated human lung adenocarcinoma cell line (A549).  Another study found gold nano-particles (4 nm size) helped in increased apoptosis in B-Chronic Lymphocytic Leukemia (CLL). Incidentally, CLL is an otherwise incurable disease predominantly characterized by resistance to apoptosis .  It is observed that the nano-medical application of various drugs is proportionate to their particle size and shape. Smaller the particle, the quicker is the cellular internalization and consequent effects. It is interesting to reiterate here that the pharmacological efficacy of a Bhasma preparation is largely attributed to the number and type of Puta (traditional incineration process) used in its making. Increased incinerations, therefore, are able to reduce particle size and subsequently give rise to increased efficacy to a given Bhasma. 
The toxicity of certain Ayurvedic formulations has become a potential limiting factor towards its globalization. Ayurvedic classic texta have taken a serious note of the potential toxicity of certain herbs, minerals and metals. A strict GMP observation is recommended to overcome inherent toxicity of these preparations. Traditionally, ayurvedic drugs are purified through Shodhana (biopurification), which are proposed to reduce drug toxicities through manual, physical or organic ways. Efficacy of Shodhana methods in reducing toxicity and enhancing safety of ayurvedic preparations was tested as early as in 1981 when Singh et al. demonstrated an improved pharmacological property and reduced toxicity in a Shodhana treated Vatsanabha (aconite) sample.  Throat and Dahanukar (1991) further elaborated this observation by comparing various traditional methods of Shodhana for their relative efficacy. In this study, Aconite processed with cow urine was found more effective and less toxic compared to other methods of Shodhana.  Unfortunately, these studies remained unnoticed for long and hence could not serve a support to establish a scientific basis to ayurvedic pharmaceutics.
Ayurveda also presents some unique clinical applications of its fundamental concepts. Rasayana is one such concept having an extensive potential applications. Rasayana drugs are described to have anti-aging effects. Labhopayo hi shastanam rasadinam rasayanam, [INSIDE:5] is statement from the Charaka Samhita (Chikitsa sthana i/i/8) that says that Rasayana,are agents thatare supportive to the qualitative improvement of tissues. A qualitative improvement here essentially refers to the functional and constitutional specifications of a tissue altered by age. Such an enhanced tissue would have optimal functions and also withstand premature aging consequent to its impaired quality. Therefore, anti-aging seems to be the secondary outcome of the Rasayana, subsequent to qualitative up-gradation and stabilization of cellswhich is its primary function. Sharangdhara's statement rasayanam cha tajghyeyam yajjaravyadhi vinashanam [INSIDE:6] is more apt for its description of the use of Rasayanas in Jaravyadhi (progeria), Jara (aging) and Vyadhi (disease).
It is for this reason that, Rasayana drugs are said to produce their beneficial effect more promptly in conditions where a suboptimal quality of tissue is leading to its premature aging and suboptimal functioning. In healthy people where the tissue aging is in connotation to the physical age, Rasayana can offer only a little to help.
Rasayana drugs are proposed to promote tissue longevity through some more novel mechanisms likeReduction of toxin/metabolic waste load within the cell through their reduced production or increased scavenging, ensuring efficient use of energy within the cell, thus requiring less substrate consumption leading to reduced energy requirement and reduced waste production, initiation of micro-repair by providing essential nutrients by participating in regeneration directly or through promotion of latent enzyme systems. 
The studies of Devasagayam et al. have added to the understanding of antioxidant action of a few Rasayana herbs of Ayurveda. The mechanism of action proposed for these herbs include suppression of free radical formation, break-chain initiation, break-chain propagation, reconstitution of membrane and repair damage. 
An approach to understand Ayurvedic pharmacology within a molecular perspective is the recent segment of interfacing between Ayurveda and molecular science. Reserpine, the active alkaloid of Sarpagandha (Rouwolfia serpentina), till today is the only molecule that blocks vesicular monoamine transporters (VMAT). This generalized blockage exposes biogenic amines to degradation by monoamine oxidize (MAO) leading to their depleted levels. This recent understanding of reserpine uniquely explains the classical indication of Sarpagandha for Unmad (mania) patients and also explains how its use may lead to biogenic amine depletion and subsequently to depressive episodes.
Ayurveda is often sought as a therapy for cancer patients. There are several common features between the ayurvedic concept of cancer and modern science. Anti-cancer medicines currently used inactivate or activate specific molecules or cell signaling pathways. Within the last three decades, cancer causing genes called oncogenes, cancer-suppressing genes (tumor suppressor genes), cancer growth factors (such as epidermal growth factor and vascular endothelial growth factor), cancer-promoting enzymes (such as cyclooxygenase [COX]-2, matrix metalloproteinase 9, inducible nitric oxide synthetase) and cancer-causing protein kinases (AKT, mitogen-activated protein kinase [MAPK], protein kinase C) have been identified as targets. Although these targets were not known 5000 years ago, the components of herbs used at that time now appear to target these molecules. For instance, nuclear factor kB, which has been known to play a major role in tumorigenesis, is targeted by the components of several herbal remedies described in Ayurveda. Similarly; several herbs have been described in Ayurveda that can suppress either expression of COX-2 or its activity. 
There are several more postulates and sporadic works, which strongly present Ayurveda in a scientific and understandable manner to a receptive mind. Thus it is felt that a reappraisal of Ayurveda in light of fundamental science and its advances would be immensely helpful to perceive Ayurveda in true scientific fervor.This article discussed a few important leads from basics of Ayurveda in light of their possible scientific correlates to reappraise them in tune to contemporary knowledge.
The very core of Ayurveda is formed from some very basic concepts e.g. panchabhautic theory, the prakriti concept which is used to describe the predisposition to and prognosis of disease as well as governs the choice of the therapy, balance and imbalance of the three dosha (vata, pitta and kapha) in the development of disease. Interestingly, Ayurveda further expands on these theories to plan interventions that would correct the imbalance. The actions of medicines are described through their various properties (like rasa, guna, veerya, vipaka,and prabhava) based inherently on their elemental composition. It is the need of the hour to use modern technology to explore the relevance of these concepts, so that they may be interpreted in light of contemporary scientific language to offer modern health care.
|1||Cooper EL. Ayurveda is Embraced by eCAM. Evid Based Complement Alternat Med 2008;1:1-2.|
|2||House of Lords select committee on science and technology. Complementary and alternative medicine. 2000 session 1999-2000 6th report, The stationary office, London.|
|3||McIntyre MA. The House of Lords select committee's report on CAM. J Altern Complement Med 2001;7:9-11.|
|4||Wootton JC. Spirit of enquiry. J Altern Complement Med 2001;7:609-11.|
|5||Rastogi S. Ayurveda for comprehensive health care. Indian J Med Ethics 2009;6:101-2.|
|6||Indian medicine.nic.in [homepage on the Internet]. India: Dept of AYUSH, Govt of India Available from: http://www.indianmedicine.nic.in. [last updated on 2008]. [last accessed on 2008 Aug 11].|
|7||Hankey A. CAM modalities can stimulate advances in theoretical biology. Evid Based Complement Alternat Med 2005;2:5-12.|
|8||Hankey A. The scientific value of Ayurveda. J Altern Complement Med 2005;11:221-5.|
|9||Wikipedia.org [homepage on internet] Origin of life available from http://en.wikipedia.org/wiki/Origin_of_life#Miller.27s_experiments [last updated on 2008]. [accessed 2008 Aug 20].|
|10||Patwardhan B, Joshi K, Chopra A. Classification of Human Population based on HLA gene polymorphism and the concept of Prakriti in Ayurveda. J Altern Complement Med 2005;11:349-53.|
|11||Prasher B, Negi S, Aggarwal S, Mandal AK, Sethi TP, Deshmukh SR, et al. Whole genome expression and biochemical correlates of extreme constitutional types defined in Ayurveda. J Transl Med 2008;6:48.|
|12||Ghodke Y, Joshi K, Patwardhan B. Traditional Medicine to Modern Pharmacogenomics: Ayurveda Prakriti Type and CYP2C19 Gene Polymorphism Associated with the Metabolic Variability. Evid Based Complement Alternat Med 2009 Dec 16. [Epub ahead of print]|
|13||Joshi RR.A biostatistical approach to Ayurveda:Quantifying the Tridosha . J Altern Complement Med 2004; 10: 879-89|
|14||Hankey A. A test of the systems analysis underlying the scientific theory of Ayurveda's Tridosha. J Altern Complement Med 2005;11:385-90.|
|15||Tripathi BN, editor. Charaka samhita Varanasi: Chaukhambha orietalia. Sutra sthana, 1994. 26/40.|
|16||Joshi K, Hankey A, Patwardhan B. Traditional phytochemistry: identification of drug by taste. Evid Based Complement Alternat Med 2006;2:145-8.|
|17||Beauchamp GK, Keast RS, Morel D, Lin J, Pika J, Han Q, et al. Breslin Phytochemistry:ibuprofen like activity in exrtra -virgin olive oil. Nature 2005;437:45-6.|
|18||Rastogi S, Chiappelli F, Bringing evidence basis to decision making in Complementary and alternative medicine (CAM): Prakriti (Constitution) analysis in Ayurveda in Evidence-based Practice towards Optimizing Clinical Outcomes . In: Chiappelli F, et al. editor. Springer; 2010.|
|19||Brown C, Bushell G R, Whitehouse M,Agrawal DS, Tupe SG, Paknikar KM, et al. Nano gold pharmaceutics(i) The use of colloidal gold to treat experimentally-induced arthritis in rat models;(ii) Characterization of the gold in Swarna bhasma,a microparticulate used in traditional Indian medicine, Gold 2006 presentation, Gold Bulletin 2007;40:3. |
|20||Rediffnews.com [Home page on internet] 18 Ayurvedic drugs violate norms: report. Available from: http:// www.rediffnews.com [last updated on 2005 Dec 9]. [last accessed on 2008 Aug 15].|
|21||Singh SK, Chaudhari A, Rai DK, Rai SB. Preparation and characterization of a mercury based Indian traditional drug Ras-Sindoor. Indian J Traditional Knowledge 2009;8:346-51. |
|22||Pyrgiotakis G, Bhowmick TK , Finton K, et al. A study of cell (A549) - particle (Jasada Bhasma) interactions using Raman spectroscopy 2008; Biopolymers, Wiley Periodicals, Inc; 2008. 10.1002/bip.20947.|
|23||Mukherjee P, Bhattacharya R, Bone N, Lee YK, Patra CR, Wang S, et al. Potential therapeutic application of gold nanoparticles in B-chronic lymphocytic leukemia (BCLL): enhancing apoptosis. J Nanobiotechnology 2007;5:4.|
|24||Kulkarni DA, editor. Rasa Ratna Samucchaya. New Delhi: Mehar Das Laxman das Publications; 1998. p. 10/48-50.|
|25||Singh LB, Bose R, Singh SP. Effect of shodhana of aconite on its pharmacological action. Ind J Pharmac 1981;13:123-4.|
|26||Throat S, Dahanukar S. Can we dispense with Ayurvedic Samsakaras? J Postgrad Med 1991;37:157-9.|
|27||Singh RH, Narasimha K, Singh G. Neuronutrient impact of Ayurvedic Rasayana therapy in brain aging. Biogerontology 2008;9:369-74.|
|28||Devasagayam TP, Tilak JC, Boloor KK, Sane KS, Ghaskadbi SS, Lele RD. Free radicals and antioxidents in human health: current status and future prospects. J Assoc Physicians India 2004;52:794-804.|
|29||Garodia P,Ichikawa H,Malani N,Sethi G,Agrawal BB,. From Ancient Medicine to Modern Medicine: Ayurvedic Concepts of Health and Their Role in Inflammation and Cancer, J Soc Integr Onc. 2007;5:1.|