Exploring Ayurvedic Knowledge on Food and Health for Providing Innovative Solutions to Contemporary Healthcare

Exploring Ayurvedic Knowledge on Food and Health for Providing Innovative Solutions to Contemporary Healthcare

Ayurveda, a traditional system of medicine that originated over three millennia ago in India, offers extensive insights about food and health based on certain unique conceptual as well as theoretical positions. Health is defined as a state of equilibrium with one’s self (svasthya) but which is inextricably linked to the environment. Ayurvedic principles, such as the tridosa (three humors) theory, provide the relationship between the microcosm and the macrocosm that can be applied in day-to-day practice. Classical Ayurveda texts cover an array of themes on food ranging from diversity of natural sources, their properties in relation to seasons and places and to their specific function both in physiological and pathological states. The epistemic perspective on health and nutrition in Ayurveda is very different from that of biomedicine and modern nutrition. However, contemporary knowledge is reinventing and advancing several of these concepts in an era of systems biology, personalized medicine, and the broader context of a more holistic transition in sciences in general. Trans-disciplinary research could be important not only for pushing the boundaries of food and health sciences but also for providing practical solutions for contemporary health conditions. This article briefly reviews the parallels in Ayurveda and biomedicine and draws attention to the need for a deeper engagement with traditional knowledge systems, such as Ayurveda. It points out that recreation of the methodologies that enabled the holistic view point about health in Ayurveda may unravel some of the complex connections with Nature.

Introduction

Ayurveda is one of the oldest healthcare systems that evolved in India. From the large number of literature spanning over three millennia on diverse aspects of managing health and wellbeing, both in Sanskrit and regional languages of the subcontinent, it can be deduced that it has had a dynamic and unbroken knowledge tradition (1). Contemporary Ayurveda has been formalized and institutionalized on aspects such as education, clinical approaches, pharmacopeia, and product manufacturing starting from late nineteenth century. In the post independence period in India, it has been recognized and legitimized as one of the formal healthcare systems of the country (2).

The term Ayurveda comprises two words – ayu (life) and veda (knowledge), thus, deals with various aspects related to health and wellbeing in their diverse aspects, such as happy life, sustainable happiness, and longevity (3). According to Ayurveda, there are three fundamental states of a being such as the physical (including physiological), mental, and the spiritual. Health is a balance of all these three states and their relationship with the outside world (4). This relationship between the microcosm and the macrocosm is yet another fundamental tenet of Ayurveda. The “being” constantly interacts with the outside world through its senses (senses of knowledge and senses of action) and the cognitive functions. At the same time, the outside world is constantly influencing the being. Both the outside world and the being are understood on the ontological basis of the pancamahabhuta or the five element theory. The categorization in terms of the five elements, including earth, water, fire, air, and space corresponds to each of the five senses, viz. smell, taste, vision, touch, and sound, respectively (3). This is a fundamental precept of all knowledge traditions in the subcontinent. But in Ayurveda for ease of understanding of physiological and pathological aspects, the five elements are further grouped into three called the tridosavata (a combination of space and air), pitta (fire), and kapha (water and earth) (Figure 1). Body and mental types, metabolic processes, biological rhythm, seasonal variations, various other physiological and pathological processes, etc. are understood in terms of innumerable permutations and combinations of these elements and the tridosa in the body. According to Ayurveda, this forms the basis of understanding of materials (Dravya guna sastra), such as food or medicine, therapeutic approaches, and dietary or lifestyle changes, to stay healthy (5). Food classifications based on their organoleptic properties and their impact on psychological constitution of an individual is yet another interesting precept of Ayurveda (6).

Figure 1. Panchamahabhutha and tridosa relationship.

While the Ayurvedic concepts and theories may appear quite generic and simplistic in its description, the sophistication is evident from the universality and contemporariness of the applications at the levels of diagnosis and line of treatment. Ayurvedic perspective of Nature and the universe and its interplay with the “being” provides opportunities that can be tapped for applications in modern health sciences and nutrition.

Concerted efforts to scientifically interpret and utilize Ayurvedic knowledge through the eyes of modern science and medicine are ongoing. The first section of the article highlights some of the basic theoretical perspectives of Ayurveda and understanding of health, food, and nutrition, while the second provides a brief overview of the trans-disciplinary research efforts to interpret and use Ayurvedic knowledge. The article introduces some of the Ayurveda concepts and principles that are pertinent to health, food, and nutrition and presents the trends in Ayurveda research.

Health and Food

Svasthya, “to be established in one’s self or own natural state” is optimal health according to Ayurveda. In order to achieve this, one has to have a balance of structural and physiological factors, metabolic and excretory processes, body tissues, senses, mind, and attain a state of self awareness and contented self (6). Ten factors (dasa vidha pariksa) are used to determine the state of health of an individual per Ayurveda namely, body tissues (dusya), residing location (desa), physical strength (bala), seasons/time (kala), digestive and metabolic processes (agni or anala), genetic and phenetic constitution (prakriti), age (vaya), mental strength or temperament (sattva), habituation (satmya), and food (ahara) (7). It is interesting to note that sattva is said to influence health. While these are mainly used for diagnostic purposes, these can also be used to measure the wellbeing of an individual.

Ahara, a Pillar of Life

Ahara is one of the three pillars of life according to Ayurveda; the other two being sleep and regulated sexual life. The classical texts of Ayurveda of 300 BC–700 AD dedicate elaborate sections on foods (6). Unique aspects include detailed descriptions of food and beverage, food classification based on their taste, therapeutic qualities, etc., food safety and measures for the same, different incompatibilities of food based on their tastes, processing, dose, time, place, etc., prescriptions of consumption, food qualities and intake based on the digestive ability of an individual, and the nature of food that is being consumed (3). Primary classification of food is based on its appropriateness to body and mental constitution based on the five elements and the tridosa theories. Five elements combine and dissociate in the natural transformation of any material, living or non-living (8).

Taste (Rasa) as an Indicator of Health Effects

One of the ways of food classification in Ayurveda is based on rasa. There are six major tastes according to Ayurveda, viz., sweet, sour, salty, pungent, bitter, and astringent. There are primary and secondary qualities (guna) that increase the properties of a material. This is further augmented by potency (virya), post digestive effect (vipaka), and therapeutic action (karma). According to Ayurveda, the classification based on rasa, guna, virya, vipaka, and karma is not only applicable to foods but also for all materials, including medicines, and is dealt with under Dravya guna sastra (the science of materials’ properties), the Ayurvedic pharmacology (8).

Food Can Alter Moods

Another interesting taxonomy of foods is based on their effect on psychological dispositions of individuals. According to Ayurveda, there is a subtle link between disease manifestation and the six psychological expressions, such as lust, anger, greed, desire, attachment, and ego. These psychological states are closely linked to foods. This connection is further discussed in terms of three states of being including sattva, rajas, and tamasSattva is the contented state, rajas an excited state whereas tamas relates to a lethargic disposition, i.e., foods can induce these states of mind (910).

Proper Metabolism is Key to Good Health

The energy that drives metabolic processes in the body is called agni, which also has an important effect on health. There are three stages in the digestive cycle starting from the gross form in the gastrointestinal tract followed by tissue-specific metabolism and elemental level metabolism. In this sequence of events, vipaka has a specific impact on the body. Generally, the predominant taste of the food material remains in the post digestive effect; but for materials with multiple tastes, the taste changes post metabolism: an important indicator of its impact on the system. For example, Indian gooseberry (amla) is predominantly sour in taste but post-digestive effect is sweet. Even though sour taste can increase pitta in the body, gooseberry nullifies pitta due to the sweet post digestive function (11). Further according to Ayurveda the action caused by a material (dravya) varies depending on the substratum (dhatu) and the contextual factors like place, time, and so on (6).

Food and Physiological Processes and Actions

In Ayurveda, food has been classified based on morphological features and their corresponding physiological actions. For example, grains, pulses, processed foods, meat and products, leafy vegetables, fruits, salts, supplements, various forms of water, milk and milk products, oils, and alcoholic drinks have been elaborated based on their effect on the body. This is further elaborated in terms of place of origin and seasonal variation (12). Food processing is a topic that is dealt with in detail. Properties of raw, dried, smoked, grilled, pickled, steamed foods, various additives and adjuvants find mention based on the pancamahabhuta theory. The pharmacological properties of a substance get altered depending on the processing. For example, puffed rice is light on the system as compared to flaked or cooked rice that is heavy to digest (13). Curd, which is unwholesome in most situations, becomes a healthy drink when churned and the butter is removed. This sweet tasting buttermilk kept in an earthen vessel for 2 days develops astringent taste and becomes a wholesome food for the gastrointestinal system especially in conditions such as hyperacidity, irritable bowel syndrome, fissures, hemorrhoids, and certain types of diarrhea and dysentery (14).

Prakriti – A Guide to Personalize Diets

An individual’s prakriti is another important determinant of the effect of food on the system. Prakriti of an individual is characterized by a set of physical, physiological, and psychological attributes. For example, based on taste preference, individuals can be grouped as vata (having affinity for sweet, sour, and salty tastes); pitta (with liking for sweet, bitter, and astringent taste), and kapha (for pungent, bitter, and astringent tastes). Whereas these tastes mitigate any negative effects of the inherited constitution, usage of tastes in the reverse order can cause imbalance in the body. For example, if a vata constitution person continuously consumes pungent, bitter, and astringent tasting materials, it could lead to rapid aging and degeneration of the body (315).

Incompatible Foods (Viruddha Ahara) and Processes

Yet another distinctive feature of Ayurveda is its understanding of incompatibilities of food materials and processing. There are 18 forms of incompatibilities according to Ayurveda (3). Incompatibilities are explained based on the potency of materials, processing, quantity/dose, process of intake, time/season; combining materials, such as sour fruits and milk or honey and ghee (clarified butter) in equal quantities; milk along with horse gram, jack fruit, or fish; or even heating honey. Whereas we may not have a contemporary scientific explanation for these, this can be explained in Ayurvedic terms as incompatibility in the nature of the materials.

Wholesome and Unwholesome Food (Pathya and Apathya)

Several examples are provided in Ayurvedic texts in terms of wholesome supplements, pathya and apathya. These are particularly indicated in disease management. For example, pomegranate, amla (Indian gooseberry), buttermilk, etc. are mentioned as good pathya ahara in the management of iron-deficiency anemia (16). Processing of a material can change the potency, safety, and pharmacological effect of the material. Curd is considered unwholesome in most dosa imbalanced conditions. There are specific instructions to consume yogurt; that it should not be taken at night, or in seasons such as spring, summer, and fall. It should be taken with sugar candy or green gram soup or honey. There are also disease-specific or medicine-specific instructions that should be followed for consumption of food. As an example, a patient suffering from cough is advised to consume vegetables, such as coccinea; spices such as garlic and cardamom, long pepper, ginger, and condiments prepared with puffed paddy (16). It is indicated that certain tastes have direct correlation with disease manifestation, hence, they are avoided during treatment of those conditions. There are also detailed descriptions of convalescence foods (17).

From the above section, it is clear that Ayurveda has its own universally applicable principles, methods, and practices that are very different from biomedicine and modern nutrition concepts (Table 1). Several efforts are ongoing to understand and interpret Ayurveda on the basis of contemporary science. A recurring criticism has been that natural science research in Ayurveda has been not adequately effective and has been limited to ethnobotany, biochemistry, and pharmacology. Most research initiatives till last decade were restricted to looking for compounds or molecules from Ayurveda drugs that could be absorbed to the modern pharmacopeia. These have not resulted in any substantial contributions in terms of new diagnostic techniques, formulations, or treatment approaches in Ayurveda except for some minor outcomes of validating certain Ayurvedic practices. This illustrates a distinct need to focus on fundamental research based on Ayurvedic principles for identifying new pathways and for more holistic perspectives in preventive as well as curative healthcare. There is much to be researched into the unique Ayurvedic concepts in nutrition, including pathya, viruddha aharakala and desa vicaraagniama, etc. (618).

 

Table 1. Epistemological comparison of modern biomedicine and Ayurveda.

Bridging Trans-Disciplinary Research

There have been several ethnobotanical explorations into Indian health knowledge systems by many western and Indian enthusiasts. Hortus malabaricus, a seventeenth-century-AD Dutch publication is an example that contains 12 volumes of information about the plants and the local uses from Malabar (better known as Kerala). The “Wealth of India,” an encyclopedic series, was published through meticulous documentation and research by scientists in national research institutions on economically important medicinal plants in the post independent India. Sporadic research efforts continue on the botanical, chemical, molecular, and pharmacological aspects of Indian medicinal plants and traditional medicine. However, in the last decade or so there has been a renaissance of sorts of Ayurveda with renewed interest in bridging Ayurveda and science, to understand and interpret Ayurvedic concepts, i.e., this interest goes beyond validating the use of medicinal materials per se to specifically unravel the concepts in Ayurveda. “A science initiative in Ayurveda” authored by M.S. Valiathan has sown the seeds by bringing in for the first time, a scheme called “Ayurvedic Biology” under the premier, mainstream, national funding agency, the Department of Science & Technology. (http://dst.gov.in/whats_new/whats_new12/AYURVEDIC%20BIOLOGY.pdf). Several concepts, including prakriti, dosa, rasayana, and panchakarma, are being researched by leading scientific institutions in the country as co-ordinated projects. Publications on research in Ayurveda can be classified as below.

Mainstream Ayurveda Research

Drug discovery, quality standardization, pharmacological, and clinical validation of the safety and efficacy of medicines have been the mainstream focus areas of Ayurveda research. Pharmacological benefits of many Ayurvedic plants and formulations are being rigorously studied and validated scientifically to be exploited in the treatment of diseases. Even though this approach was being practiced since the early twentieth century, it has gained new impetus subsequent to the christening of the approach as “Reverse Pharmacology.” Reverse pharmacology is “the science of integrating bedside documented experiential hits into leads by trans-disciplinary exploratory studies and to further develop these leads into drug candidates by state-of-art experimental and clinical research” (1920) Some well studied plants using the reverse pharmacology approach have been Turmeric (Curcuma longa), Asvagandha (Withania somnifera), Brahmi (Bacopa monnieri), Sarpagandha (Rauwolfia serpentina), Neem (Azadirachta indica), Guggulu (Commiphora mukul), Guduchi (Tinospora cordifolia), Indian gooseberry (Phyllanthus emblica), Kizhanelli (Phyllanthus amarus), Pomegranate (Punica granatum), Vidanga (Embelia ribes), and Bakuchi (Psoralea corylifolia). Compounds isolated from a few of the Ayurvedic plants have gone on to becoming drugs or nutraceuticals, such as reserpine, embelin, azadirachtin, and curcumin (21). In India, New Millennium Indian Technology Leadership (NMITLI), the partnership program of premier national institutions and industry, led to the scientific exploration of Ayurvedic formulations to develop drugs for arthritis, diabetes, and psoriasis (20).

Official pharmacopeias, including the Indian Pharmacopeia and Ayurvedic Pharmacopeia of India bring out monographs that provide botanical and chemical characterization of herbs and formulations as per routine modern scientific methods. Finer aspects of traditional wisdom regarding the quality, including time and place of collection rarely get reflected in these monographs. However, traditional knowledge guided quality standardization of herbal medicines was proposed as a better strategy showing a few preliminary experimental findings (2223), calling the approach as Reverse Pharmacognosy (24). Despite Ayurvedic treatments being more than a drug-based therapy, including diet, massage, yoga, etc., until recently, Ayurvedic medicines were put through the same clinical trial protocols as modern drug trials. However, recent thoughts regarding whole system trials call for a different approach that can do justice to holistic Ayurvedic treatments (2526).

Research into Ayurvedic Concepts

It was being increasingly recognized by Ayurveda scholars and Ayurveda-Science enthusiasts that not much was being done to unravel the concepts in Ayurveda (2728). Certain efforts are opening up new dialogs with Ayurveda, bioscience, and biomedicine, some of which are listed below. The example below is just to indicate the ongoing trans-disciplinary research trends and is not intended as a comprehensive review of published literature.

Ontology and Theories

Ontology is a systematic account of existence. In Ayurveda, the method of “knowing” through experimentation and direct evidence can be compared to “Pratyaksa pramana,” which is only one of the four ways of “knowing.” Aptopadesa (knowledge gained from certain individuals who have foregone material needs), Anumana (observation), and Yukti (logical conclusion from observed phenomena) are the three other ways (3). Galilean and Cartesian philosophies adopt reductionist methods and experimental verification, which are the premise of biomedicine (29). The main challenge in comparing the ontologies of the two systems pertains to the lack of appropriate vocabulary to share and interpret (30). Also, the lack of exact comparable entities owing to different epistemologies of the two systems may be the other hurdle. The exact biomedical definition of terminologies, such as Pancamahabhutatridosa, i.e., vata, pitta, and kaphadravya guna sastraprakritiagniama, and several others, does not exist today, nor can they be likened to a single entity (18).

A glossary of Ayurvedic terms used in the article has been provided in Table 2 to provide a gross level understanding.

Table 2. Glossary of Ayurvedic terms

Ayurvedic Biology and Systems Biology

Ayurvedic principles are largely holistic and based on an epistemology that is very different from modern biomedicine (Table 1), which is more reductionist in its approach. The ontologies of the two systems are different as mentioned above. The methods and instruments used in biomedicine are designed to understand genes, atoms, molecules, cells, tissues, and organisms. Well-disciplined and calibrated sensory organs and mind were used as instruments in Ayurveda to perceive, understand, and theorize fundamental unifying patterns in Nature. From a theoretical point of view, focus on systemic and functional aspects of health and diseases; multi-causality approach; a circular method of cause–effect reasoning; subjective, qualitative, individualized, personalized, and immunity-centered, stage-wise management; and attribution of importance to physicians’ wisdom are a few notable features of Ayurveda and other traditional medical systems (31). The focus in such a management approach is not only physical but also mental and spiritual. This is quite different from the biomedical approach that is largely structural; organ specific and localized; single causality approach based on linear reasoning; organism centered; objective; quantitative; universalized; mostly curative; and drug-based targeted medicine approach. Whereas the Ayurvedic approach is individual physician centered as against the institutional approach of modern medicine (31). New species of plants or diseases or management methods are incorporated into the repository of knowledge as and when they are understood on Ayurveda principles and utilized. Specific focus on side effect along with effect is of high concern in the Ayurvedic approach as evidenced in the design of polyherbal formulation containing a main drug and supportive drugs.

Ayurveda has a top-down, holistic understanding of organisms and their interactions with the environment at a functional level and not so much at the molecular level. The practical application of the tridosa theory, for example, is grossly valid across viewing and understanding Nature, balancing health by using natural materials and in diagnosis and line of treatment of diseases (32). Biomedicine, on the other hand, has a bottom-up approach that understands the structural basis and molecular processes of cells, tissues, and organs and a not so much of the functional networks within a system and its interactions with the environment. The current day Systems Biology approach aims to be more holistic but is also derived from a systematic synthesis of data obtained from the reduced view of a system, using extensive computational and mathematical modeling of the inter-linkages.

Prakriti and Ayurgenomics

Ayurveda has a unique way of classifying humans, which is used in the clinical management of health and disease. Humans are classified into three fundamental types of constitution or prakriti, called vata, pitta, and kapha based on their anatomical, physiological, and psychological characteristics. According to Ayurveda, prakriti of a person is determined at the time of conception and does not change until death. Recommendations on diets, lifestyles, and drugs vary depending on the prakriti of the individual (3). Since it gets determined at the time of conception, in the past decade, the hypothesis that prakriti has a genetic basis was tested by different groups of Indian scientists. A correlation between specific prakriti and HLA-DRB1 polymorphism was demonstrated by Bhushan et al., (33). Prasher et al. (34) and Mukherjee and Prasher (35) have used prakriti-based classification and have demonstrated the genomic and biochemical correlates with specific prakriti types. They have termed this approach of classification of humans as Ayurgenomics and propose its potential use in personalized and preventive medicine. Frequency of association of CYP2C19 genotype was demonstrated to vary depending on the prakriti (36). Differential expression of a high-altitude adaptation gene, EGLN1 as a response to hypoxia, was correlated to specific prakriti type (37). Rotti et al. (38) found a significant correlation between dominant prakriti to place of birth and body mass index (BMI).

Rasayana

Rasayana is a branch of Ayurveda that deals with methods to enhance quality of life and extend lifespan. It mentions plants, animal products, metals, and minerals that can be used as Rasayana materials to delay aging and enhance wellbeing. It also describes the non-material-based methods, including meditation, good thoughts, conduct, and lifestyle that can influence well being. Rasayanas are useful in preventive, promotive, and curative health. They are said to mainly act in three possible ways (i) Agnivyapara: by regulating agni that drives transformations in the body, like the metabolic processes, (ii) Srotosodhana: by clearing the macro and micro channels thereby increasing tissue perfusion, and (iii) Posana: by nourishing tissues (3940). Apart from tissue nourishment or perfusion, it is also to create balance of dosa that facilitates adequate space, optimal movement and degeneration, regulated metabolism/transformation, and optimal softness and hardness of the physical structure. According to Ayurveda, if the above three are streamlined, the body is maintained in optimal health (1). Even though this makes a lot of common sense at the gross level, it is a challenge to test these concepts in its entirety.

Research into Rasayana is at a heightened state today due to the contemporary interest in anti-aging, rejuvenation, and focus on wellness. Age-related diseases, such as Alzheimer’s, Parkinson’s, arthritis, atherosclerosis, and so on, can benefit by probing the concept of Rasayana. Contemporary bioassay tools such as in vitro and small organisms such as Drosophila, Caenorhabditis elegans, yeast are now being used to observe the physical, physiological, and behavioral effect of Rasayanas and gain insights into the molecular mechanisms of action (41). Several studies have shown that Rasayana plants have anti-oxidant, adaptogenic (42), anti-inflammatory (4345), anti-cancer (46), and anthelmintic (47) activities. Pomegranate, a pathya fruit according to Ayurveda was shown to enhance the lifespan and health span in the fruitfly (Drosophila melanogaster) model (48). Pippali (Piper longum L.) and amla (Phyllanthus emblica) were shown to be effective bioavailability enhancers due to the inherent ability to increase agni and thereby digestion and absorption. In vitro cell free and cell (Caco-2 and HepG2)-based models (49) were used as bioassay tools. Pharmacokinetics and dynamics of ­piperine – an active constituent of Pippali is also reported (5051). Pre-clinical studies on Medhya Rasayana (Ayurvedic nootropics) such as Asvagandha, turmeric, and brahmi have demonstrated the ability to clear amyloid-β plaques in neurons that are observed in Alzheimer’s disease (52). Research into Rasayana holds the potential to unravel diet and herbs-based preventive methods to curb neurodegeneration and aging, in general.

Dravya Guna Sastra

Dravya guna Sastra literally means “material properties science.” Ayurvedic pharmacology classifies materials based on the sensorial and pharmacodynamic effects on the body. Rasagunavirya, and vipaka determine the karma that a drug or material would have on the body. Not much research has gone into furthering the trans-disciplinary understanding of the five parameters (Rasapancaka) that classify a dravya. However, there are a few commentaries and hypotheses drawing parallels. In Ayurveda, rasa is said to be the total sensory experience involving the nose, tongue, and throat, based on which six types of rasas have been defined, namely madhuraamlalavanakatutikta, and kasaya. A well-balanced Ayurvedic diet would always have the six tastes (sad rasas), which in turn plays a role in homeostasis. Excessive intake of one or the other rasas can tilt the equilibrium leading to a health problem. As an example excessive intake of sweet tasting foods can lead to obesity, pungent tasting foods to acidity, etc. (653).

“The strength, complexion, immunity etc. of a living system is under the control of diet which in turn is under the control of six rasas” – Susruta Samhita, Sutra Sthana, Chapter 1, verse 28 (54).

Also, dosa imbalances in the body can be countered using materials with specific tastes. In jvara (fever), there is an aggravation of pitta dosa and is countered by bitter tasting drugs that pacify pitta like Andrographis paniculata or Azadirachta indica (5).

The four main tastes recognized in modern bioscience are sweet, sour, salty, and bitter (55). Conventional bioscience does not recognize pharmacological attributes to tastes. Only in the last decade, there have been studies showing the possibility of a correlation between taste and pharmacology. Beauchamp et al. (56) correlate the anti-inflammatory property to the pungency of oleocanthal (a compound found in olive oil) and ibuprofen (56).

Joshi et al. (57) hypothesize that the possible combinations of rasa in Ayurveda probably correlate with specific enzyme active sites in the body. They speculate that the number of distinguishable tastes formed by the permutation-combination of the six tastes is more than enough to distinguish the molecular shapes binding to all enzyme active sites in the body. However, in 1993, Shallenberger rejected the role of taste in any enzymatic reaction because he says that unlike in enzyme reaction there is no change in the substrate during taste perception. Palmer (58) looks at taste as a chemical inducer of signal transduction by binding to G-protein-coupled receptors (GPCRS) and proposes taste signaling as an amenable tool to the methods of pharmacology. The review by Rath et al. (59) on the scientific basis of rasa discusses the importance of structure–function relationship of chemicals but stops short of correlating it with rasas.

Network Pharmacology and Ayurvedic Network Pharmacology

The next paradigm in drug discovery is touted to be network pharmacology. Designer drugs with exclusively selective ligands to avoid side effects may become a thing of the past because a growing body of knowledge in the post-genomic biology era is revealing that drug action cannot be simplified to one drug–one target–one disease theory as understood earlier. It is more complex than a simple lock and key mechanism. There could be several “locks” (drug targets) opened by the same “key” (drugs) and several keys that can open the same lock (6061). Traditional medicine-based polyherbal formulations have been studied using -omics technologies and proposed as new strategies in drug discovery instead of single molecule-based drugs to tackle disease complexity (6263). In a recent publication, the method and concept of network pharmacology were extended to the analysis of a classical Ayurvedic formulation to understand the rationale and putative synergistic actions of ingredients in a traditional formulation (63).

Conclusion

Ayurvedic theories and practices on health, food, and nutrition are quite different from those of biomedicine and modern nutrition. Systematic exploration can provide new insights to health and nutritional sciences to provide contemporary solutions in healthcare, for instance, how one can modulate the diet and lifestyle to suit one’s prakriti, age, and season. Rasayana in particular is an area worth exploring for new ways of rejuvenation and anti-aging. Healthcare costs are a major concern to the government exchequers of both developing and developed countries. Knowledge as to how to manage health at an individual level can help bring down sky rocketing healthcare costs through providing wellness. The Ayurvedic principles and practices can potentially become relevant for designing an integrated health care strategy. Concepts in Ayurveda, such as the rasa of a material being an indicator of its action on the body, are new to biomedicine and the modern nutritional sciences and can provide practical ways to create balanced diets.

Two main observations emerged from an analysis of published literature particularly from India on the bridging efforts. There have been more articles hypothesizing correlation of certain Ayurvedic concepts with biomedical entities than actual scientific studies to illustrate the correlation. Second, wherever there have been experimentation and scientific studies to prove the hypothesis, an Ayurvedic concept or an entity has been correlated with an already existing/evolving biomedical or science paradigm rather than introducing a new paradigm from Ayurveda. This approach appears somewhat “forced,” may be because the bridging effort is being attempted by mainstream scientists and/or just because of lack of know-how to study the “holism” of Ayurveda. To state that this approach can only help look at parts of Ayurveda and not the whole is commonplace. However, there is no denying that this is most needed and that this active interest taken by biomedical scientists in Ayurveda will create new knowledge (27).

“I cannot claim that Ayurvedic Biology helps, or will help Ayurveda or Biology. Neither needs help. However, when new science, new techniques are applied to old science, new sprouts of knowledge would appear”

- M.S. Valiathan [eminent cardiologist, medical scientist and a learned scholar of Ayurveda] (64).

In recent years, there have been concerted research efforts to understand Ayurvedic principles, such as prakritidosa, and agni using modern scientific tools. These trans-disciplinary bridging efforts have no doubt helped correlate certain reduced aspects of Ayurveda with existing biomedical entities. However, they have not been able to capture the holism of Ayurveda. It is not clear whether the holistic knowledge of Ayurveda was assembled by putting together pieces of data and information gained over a period of time (like is done in Systems Biology approach) or whether there was an altogether different method adopted to perceive holism. Therefore, interpreting or validating the complex holistic principles, such as the five fundamental elements and the three bio-effector concepts (three humors or tridosas), of Ayurveda can be quite a challenge using the same methods and tools that look at cells and atoms. This may end up like the five blind men trying to interpret an elephant by feeling different parts of the elephant.

However, the post-modern scientific perspectives and methodologies in systems biology, pharmaco- and nutri-genomics, personalized medicine, chaos theory, ecological human being, etc., are today better equipped to engage in a dialog with Ayurveda than conventional biomedicine. Recreating Ayurvedic methodologies may hold the clue to understand Ayurveda holistically. This is of course not easy and would require a deeper engagement with Ayurveda.

Author Contributions

UP has contributed the introductory section, sections on the traditional knowledge aspects, and part of the bridging transdisciplinary research section and conclusion. PV has contributed to the introduction section and has written the transdisciplinary research and the concluding sections.

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgment

The authors wish to thank Dr. Subrahmanya and Balasubramani for the corrections and comments.

References

1. Sharma PV, editor. History of Medicine in India. New Delhi: Indian National Science Academy (1992). p. vii–xii.

Google Scholar

2. Anonymous. Report of Procedings: International Workshop-Integrating Traditional South-Asian Medicine into Modern Healthcare Systems. New Delhi: Jawaharlal Nehru University (JNU) (2015). Available from: www.jnu.ac.in/SSS/CSMCH/ITSAMMHCS.pdf. [cited 2015 Sep 7]

Google Scholar

3. Sharma PV, editor. Caraka Samhita. (Vol. 1). Varanasi: Chaukhambha Orientalia (2001). p. 5–9,190,228,375–6.

Google Scholar

4. Sharma PV, editor. Susrutha Samhitha. (Vol. 1). Varanasi: Chaukhambha Visvabharati (2004). 173 p.

Google Scholar

5. Sastry JLN. Dravyaguna Vijnana, Part 1. 1st ed. Varanasi: Chaukhambha Orientalia (2009). p. 1–2.

Google Scholar

6. Payyappallimana U, Venkatasubramanian P. In: Verotta L, Pia Macchi M, Venkatasubramanian P, editors. Principles of Ayurveda for Food, Nutrition, and Health in Connecting Indian Wisdom and Western Science – Plant Usage for Nutrition and Health. New York: CRC Press (2015). p. 15–36.

Google Scholar

7. Murthy KRS, editor. Vagbhata’s Astanga Hrdayam. 5th ed. (Vol. 1). Varanasi: Chaukhambha Orientalia (2001). p. 53–7.

Google Scholar

8. Dhyani SC. Rasapanchaka. Varanasi: Krishnadas Academy (1994). p. 32–42, 46–60.

Google Scholar

9. Prabhupada BS, editor. Bhagavadgita Yatharupa. 19th ed. Bangalore: ISKCON (2002). p. 736–8. [Kannada Language translation].

Google Scholar

10. Murthy KRS, editor. Astanga Samgraha of Vagbhata. 1st ed. (Vol. 2). Varanasi: Chaukhambha Orientalia (1996). 102 p.

Google Scholar

11. Dwarakanatha C. Digestion and Metabolism in Ayurveda. Varanasi: Chaukhambha Krishnadas Academy (2003). p. 48–53, 59–61.

Google Scholar

12. Sharma PV, editor. Astanga Samgraha of Vagbhata. 6th ed. (Vol. 1). Varanasi: Chaukhambha Orientalia (2002). p. 81–114.

Google Scholar

13. Sastri K, editor. Caraka Samhita, Part-1. 5th ed. Varanasi: Chaukhambha Sanskrit Sansthan (1997). p. 555–8.

Google Scholar

14. Kukkupuni SK, Shashikumar A, Venkatasubramanian P. Fermented milk products: probiotics of ayurveda. J Med Nutr Nutraceut (2015) 4:14–21. doi: 10.4103/2278-019X.146149

CrossRef Full Text | Google Scholar

15. Dey S, Pahwa P. Prakriti and its associations with metabolism, chronic diseases, and genotypes: possibilities of new born screening and a lifetime of personalized prevention. J Ayurveda Integr Med (2014) 5(1):15–24. doi:10.4103/0975-9476.128848

PubMed Abstract | CrossRef Full Text | Google Scholar

16. Tripati B. Pathyapathyanirnayah. Delhi: Chaukhambha Sanskrit Pratishtan (1998). p. 2–4,39.

Google Scholar

17. Rastogi S, Chaudhari P. In: Rastogi S, editor. Convalescent Food Practices in Ayurveda in ‘Ayurvedic Science of Food and Nutrition. New York: Springer-Verlag (2014). p. 67–80.

Google Scholar

18. Payyappallimana U. Health and Well-Being in Indian Local Health Traditions. In: Morandi A, Nambi ANN, editors. An Integrated View of Health and Well-being: Bridging Indian and Western Knowledge. Dordrecht: Springer Netherlands (2015). p. 99–113.

Google Scholar

19. Vaidya ADB. Reverse pharmacological correlates of ayurvedic drug actions. Indian J Pharmacol (2006) 38(5):311–5. doi:10.4103/0253-7613.27697

CrossRef Full Text | Google Scholar

20. Patwardhan B, Mashelkar RA. Traditional medicine-inspired approaches to drug discovery: can ayurveda show the way forward? Drug Discov Today (2009) 14(15/16):804–11. doi:10.1016/j.drudis.2009.05.009

PubMed Abstract | CrossRef Full Text | Google Scholar

21. Patwardhan B, Vaidya ADB, Chorghade M. Ayurveda and natural products drug discovery. Curr Sci (2004) 86(6):789–99.

Google Scholar

22. Sudha PVB, Geeta UG, Venkatasubramanian P. Bioactivity of traditional preparation of Piper longum L. (Piperaceae). J Trop Med Plants (2004) 5(2):179–82.

Google Scholar

23. Shankar D, Unnikrishnan PM, Venkatasubramanian P. Need to develop inter-cultural standards for quality, safety and efficacy of traditional Indian systems of medicine. Curr Sci (2007) 92(11):1499–505.

Google Scholar

24. Venkat P. Reverse pharmacognosy: a novel approach to standardise ISM drugs. Presented at the Eighth Oxford Annual International Conference on the Science of Botanicals. (2009). Available from: http://crism.net/news/pdf/rev_pharmacog_olemiss_padma_venkat.pdf

Google Scholar

25. Mathur A, Sankar V. Standards of reporting ayurvedic clinical trials-Is there a need? J Ayurveda Integr Med (2010) 1(1):52–5. doi:10.4103/0975-9476.59828

PubMed Abstract | CrossRef Full Text | Google Scholar

26. Furst DE, Venkatraman MM, Krishna SBG, McGann M, Booth-Laforce C, Ram MP, et al. Well controlled, double-blind, placebo-controlled trials of classical ayurvedic treatment are possible in rheumatoid arthritis. Ann Rheum Dis (2011) 70(2):392–3. doi:10.1136/ard.2010.136226

CrossRef Full Text | Google Scholar

27. Valiathan MS. Towards Ayurvedic Biology: A Decadal Vision Document-2006. Bangalore: Indian Academy of Sciences (2006). p. 1–34.

Google Scholar

28. Singh RH. Exploring issues in the development of ayurvedic research methodology. J Ayurveda Integr Med (2010) 1(2):91–5. doi:10.4103/0975-9476.65067

PubMed Abstract | CrossRef Full Text | Google Scholar

29. Fuenmayor R. The roots of reductionism: a counter-ontoepistemology for a systems approach. Syst Pract (1991) 4(5):1–28. doi:10.1007/BF01104460

CrossRef Full Text | Google Scholar

30. Nayak J. Ayurveda research: ontological challenges. J Ayurveda Integr Med (2012) 3(1):17–20. doi:10.4103/0975-9476.93942

PubMed Abstract | CrossRef Full Text | Google Scholar

31. Unnikrishnan PM. Inteculturality in Ayurvedic Practice. Heritage Amruth (2009) 4(6):10–16.

Google Scholar

32. Hankey A. Establishing the scientific validity of Tridosha. Anc Sci Life (2010) 29(3):6–18.

Google Scholar

33. Bhushan P, Kalpana J, Arvind C. Classification of human population based on HLA gene polymorphism and the concept of Prakriti in Ayurveda. J Altern Complement Med (2005) 11(2):349–53.

Google Scholar

34. 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. doi:10.1186/1479-5876-6-48

PubMed Abstract | CrossRef Full Text | Google Scholar

35. Mukerji M, Prasher B. Ayurgenomics: a new approach in personalized and preventive medicine. Sci Cult. New Delhi, India: Institute of Genomics and Integrative Biology (2011) 77(1–2):10–7.

Google Scholar

36. 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 (2011) 2011:249528. doi:10.1093/ecam/nep206

CrossRef Full Text | Google Scholar

37. Aggarwal S, Negi S, Jha P, Singh PK, Stobdan T, Pasha MA, et al. EGLN1 involvement in high-altitude adaptation revealed through genetic analysis of extreme constitution types defined in ayurveda. Proc Natl Acad Sci U S A (2010) 107(44):18961–6. doi:10.1073/pnas.1006108107

PubMed Abstract | CrossRef Full Text | Google Scholar

38. Rotti H, Raval R, Anchan S, Bellampalli R, Bhale S, Bharadwaj R, et al. Determinants of prakriti, the human constitution types of Indian traditional medicine and its correlation with contemporary science. J Ayurveda Integr Med (2014) 5(3):167–75. doi:10.4103/0975-9476.140478

PubMed Abstract | CrossRef Full Text | Google Scholar

39. Singh RH, Narasimhamurthy K, Singh G. Neuronutrient impact of Ayurvedic Rasyana therapy in brain ageing. Biogerontology (2008) 9:369–74. doi:10.1007/s10522-008-9185-z

CrossRef Full Text | Google Scholar

40. Balasubramani SP, Venkatasubramanian P, Kumar SK, Patwardhan B. Plant-based rasayana drugs from ayurveda. Chin J Integr Med (2011) 17(2):88–94. doi:10.1007/s11655-011-0659-5

PubMed Abstract | CrossRef Full Text | Google Scholar

41. Dwivedi V, Anandan EM, Mony RS, Muraleedharan TS, Valiathan MS, Mutsuddi M, et al. In vivo effects of traditional ayurvedic formulations in Drosophila melanogaster model relate with therapeutic applications. PLoS One (2012) 7(5):e37113. doi:10.1371/journal.pone.0037113

PubMed Abstract | CrossRef Full Text | Google Scholar

42. Rege NN, Thatte UM, Dahanukar SA. Adaptogenic properties of six rasayana herbs used in ayurvedic medicine. Phytother Res (1999) 13(4):275–91. doi:10.1002/(SICI)1099-1573(199906)13:4<275::AID-PTR510>3.3.CO;2-J

PubMed Abstract | CrossRef Full Text | Google Scholar

43. Shyni GL, Ratheesh M, Sindhu G, Helen A. Anti-inflammatory and antioxidant effects of Jeevaneeya Rasayana: an ayurvedic polyherbal formulation on acute and chronic models of inflammation. Immunopharmacol Immunotoxicol (2010) 32(4):569–75. doi:10.3109/08923970903584890

PubMed Abstract | CrossRef Full Text | Google Scholar

44. Aggarwal BB, Prasad S, Reuter S, Kannappan R, Yadev VR, Park B, et al. Identi­fication of novel anti-inflammatory agents from ayurvedic medicine for prevention of chronic diseases: “reverse pharmacology” and “bedside to bench” approach. Curr Drug Targets (2011) 12(11):1595–653. doi:10.2174/138945011798109464

CrossRef Full Text | Google Scholar

45. Singh AK. Rationality of rasayana therapy as adoptogenic, antioxidant and anti-inflammatory agent. Intl Res J Pharm (2011) 2(12):259–60.

Google Scholar

46. Datta S, Mishra RN. Plumbago zeylinica Linn. (Chitrak) – review as rasayan (rejuvenator/antiaging). Int J Res Pharm Biomed Sci (2012) 3(1):250–67.

Google Scholar

47. Venkatasubramanian P, Godbole A, Vidyashankar R, Kuruvilla GR. Evaluation of traditional anthelmintic herbs as substitutes for the endangered Embelia ribes, using Caenorhabditis elegans model. Curr Sci (2013) 105(11):1593–8.

Google Scholar

48. Balasubramani SP, Mohan J, Chatterjee A, Patnaik E, Kukkupuni SK, Nongthomba U, et al. Pomegranate juice enhances healthy lifespan in Drosophila melanogaster: an exploratory study. Front Public Health (2014) 2(245):245. doi:10.3389/fpubh.2014.00245

PubMed Abstract | CrossRef Full Text | Google Scholar

49. Venkatasubramanian P, Koul IB, Varghese RK, Koyyala S, Shivakumar A. Amla (Phyllanthus emblica L.) enhances iron dialysability and uptake in in vitro models. Curr Sci (2014) 107:1859–66.

Google Scholar

50. Khajuria A, Thusu N, Zutshi U. Piperine modulates permeability characteristics of intestine by inducing alterations in membrane dynamics: influence on brush border membrane fluidity, ultrastructure and enzyme kinetics. Phytomedicine (2002) 9(3):224–31. doi:10.1078/0944-7113-00114

PubMed Abstract | CrossRef Full Text | Google Scholar

51. Shoba G, Joy D, Joseph T, Majeed M, Rajendran R, Srinivas PS. Influence of piperine on the pharmacokinetics of curcumin in animals and human volunteers. Planta Med (1998) 64(4):353–6. doi:10.1055/s-2006-957450

PubMed Abstract | CrossRef Full Text | Google Scholar

52. Tiwari SK, Pandey YK. Ayurvedic drugs in prevention and management of age related cognitive decline: a review. Int J Pharm Sci Drug Res (2012) 4(3):183–90.

Google Scholar

53. Viswanathan MV, Unnikrishnan MV, Komatsu K, Fushimi H, Basnet P. A brief introduction to ayurvedic system of medicine and some of its problems. Indian J Tradit Knowl (2003) 2(2):159–69.

Google Scholar

54. Acharya YT, editor. Susrutha Samhitha with Dalhana Tika. Varanasi: Chaukhambha Orientalia (1992). p. 7.

Google Scholar

55. Shallenberger. Taste Chemistry. Glasgow: Blackie Academic & Professional (1993). 528 p.

Google Scholar

56. Beauchamp GK, Keast RS, Morel D, Lin J, Pika J, Han Q, et al. Ibuprofen-like activity in extra virgin olive oil. Nature (2005) 437:45–6. doi:10.1038/437045a

CrossRef Full Text | Google Scholar

57. Joshi K, Hankey A, Patwardhan B. Traditional phytochemistry: identification of drug by ‘taste’. Evid Based Complement Alternat Med (2007) 4:145–8. doi:10.1093/ecam/nel064

PubMed Abstract | CrossRef Full Text | Google Scholar

58. Palmer RK. The pharmacology and signaling of bitter, sweet, and umami taste sensing. Mol Interv (2007) 7(2):87–98. doi:10.1124/mi.7.2.9

PubMed Abstract | CrossRef Full Text | Google Scholar

59. Rath SK, Panja AK, Nagar L, Shinde A. The scientific basis of rasa (taste) of a substance as a tool to explore its pharmacological behavior. Anc Sci Life (2014) 33:198–202. doi:10.4103/0257-7941.147419

PubMed Abstract | CrossRef Full Text | Google Scholar

60. Hopkins AL. Network pharmacology. Nat Biotechnol (2007) 25(10):1110–1. doi:10.1038/nbt1007-1110

CrossRef Full Text | Google Scholar

61. Yildirim MA, Goh KI, Cusick ME, Barabási AL, Vidal M. Drug-target network. Nat Biotechnol (2007) 25(10):1119–26. doi:10.1038/nbt1338

PubMed Abstract | CrossRef Full Text | Google Scholar

62. Ulrich-Merzenich G, Panek D, Zeitler H, Vetter H, Wagner H. Drug development from natural products: exploiting synergistic effects. Indian J Exp Biol (2010) 48(3):208–19.

PubMed Abstract | Google Scholar

63. Chandran U, Mehendale N, Tillu G, Patwardhan B. Network pharmacology: an emerging technique for natural product drug discovery and scientific research on ayurveda. Proc Indian Natn Sci Acad (2015) 81(3):561–8.

Google Scholar

64. Joshi K. Insights into ayurvedic biology – a conversation with Professor M.S. Valiathan. J Ayurveda Integr Med (2012) 3:226–9. doi:10.4103/0975-9476.104450

CrossRef Full Text | Google Scholar

Citation

By Payyappallimana U and Venkatasubramanian P (2016)
Exploring Ayurvedic Knowledge on Food and Health for Providing Innovative Solutions to Contemporary Healthcare.
Front. Public Health 4:57. doi: 10.3389/fpubh.2016.00057