The nutritional facts of bamboo shoots and their usage as important traditional foods of Northeast India.
Bamboos belonging to family Poaceae are considered as one of the most versatile multiutility forest tree grasses. Though distribution of bamboos is worldwide with over 1250 species, their presence is predominantly found in Southeast Asia [1, 2]. They are known to have more than 1500 uses and are considered as one of the most economically
important plants in the world . The applicability of bamboos is highly diverse as they are employed immensely in paper, handicraft industry, house construction, and making furniture, water pipes, storage vessels and other important household items . People from different countries address bamboos in different names because of their highly multipurpose properties. The Chinese called bamboos as "Friends of the people," Vietnamese as "My brother," and Indians as "Green Gold" Bamboos in addition to their multiple applications have another important usage in utilizing their juvenile shoots as popular food items. The presence of high content of protein, amino acids, minerals, fibre, carbohydrates, and low fat makes the bamboo shoot one of the widely acclaimed nutrient rich food items. Also the presence of phytosterols in young shoots provides youthful feeling, athletic energy, and longevity to regular consumers. Bamboos shoots are popular in Asiatic countries and form a major component of their traditional cuisines . The people of Northeast India with their mongoloid features are endowed with rich bamboo culture and the plants are inseparable part of several diverse traditions and religious beliefs of many ethnic people residing at both hilly and plain areas. Consumption of bamboo shoots as food in India is mainly confined to the Northeast states where they are taken either fresh at the time of harvesting season or dried, fermented or pickled forms during offseason . The bamboo shoots are the integral constituents of many of the popular traditional cuisines. The present review explores the nutritive values and health benefits of bamboo shoots and the necessity of proper processing methods to generate nontoxic consumable bamboo products. The use of bamboo shoots as traditional foods of Northeast India and the potential and prospect of bamboo shoot industry in the region along with the importance of effective bamboo conservation through micropropagation are also highlighted.
2. Nutrient Composition of Bamboo Shoots
Bamboo shoots have immense potential of being used as important health food as they contain high proteins, amino acids, carbohydrates, many important minerals, and vitamins . Freshly collected bamboo shoots have good amount of thiamine, niacin, vitamin A, vitamin B6, and vitamin E [13,14]. Also the bamboo shoot based diets are rich source of dietary fibres and phytosterols and less cholesterol contents which make them one of the popular natural health foods. Table 1 shows the comparison of nutritive values of shoots of edible bamboos with some of the popularly consumed vegetables in different parts of the world. The nutrient compositions of shoots of different edible bamboo species have been analysed by several workers [6,13,15-18]. The nutrient contents of some important edible bamboo species is given in Table 2. Bamboo shoots contain generally tyrosine, arginine histidine, and leucine as amino acids. The presence of tyrosine facilitates biochemical metabolism of our body as it is a major constituent of adrenals which are precursors for adrenaline, necessary for active body metabolic activities. It also plays important role in function of thyroid and pituitary glands which are involved in producing and regulating hormones in human body. Presence of high fibre and phytosterols in bamboo shoot reduces fat and cholesterol levels of blood making them one of the most sought after health foods among patients with life style related disorders. The dietary fibre possesses number of health benefits as it controls blood pressure, hypertension, and obesity and also protects our body from coronary diseases and potential carcinogens [19, 20]. The survey conducted by Kalita and Dutta  showed that some ethnic tribes of Northeast India used bamboo shoots to control high blood pressure and cardiovascular ailments. The high dietary fibres and low fat in bamboo shoot help in reducing the thickening of arteries maintaining the blood pressure. Park and John  conducted a study to show that diet containing bamboo shoots had reducing effect on serum content of total cholesterol and low density lipoprotein. There was increase in the frequency of bowel movement and faecal volume indicating its role in cholesterol lowering and diabetes prevention in individuals provided with bamboo diets. There are instances of using bamboo shoots by Karbi Anglong tribes of India to control early stage of cancer . The anticancer property of bamboo shoots might be attributed to the presence of lignans and phytosterols. The production of carcinogens, growth of cancer cells, cell invasion, and metastasis are inhibited by phytosterol . Regular intake of bamboo shoots reduces reproductive health related problems in female. Bamboo shoots are used by local tribes belonging to Bodo, Thadau, Mosang, and Tiwa for treatment of irregular menstrual cycle, heavy bleeding after delivery, infertility problems, reducing labour pain, and also for inducing puberty in young female. Though scientifically not proven some tribes believe bamboo shoot causes abortion in pregnant women. They are often advised not to consume bamboo shoot during the first trimester of pregnancy.
2.1. Amino Acids. Bamboo shoots have rich amount of amino acids. Out of 17 amino acids reported in bamboo shoots, 8 amino acids were essential for human body . Nirmala et al.  studied amino acid content of freshly harvested, fermented, and canned shoots of Dendrocalamus giganteus. There was decreased amount in amino acid in fermented (2.005 g/100 g fresh weight) and canned shoots (1.980 g/100 g fresh weight) as compared to freshly collected juvenile shoots (3.863 g/100 g fresh weight). Giri and Janmejay  reported reduction of individual amino acid content in 300-day-old bamboo shoots of Bambusa tulda. Kozukuen et al.  observed the presence of tyrosine as the most abundantly free amino acids in young shoots of Phyllostachys pubescens. The amount of amino acids in bamboo shoots of five species of Bambusa and another four species of Dendrocalamus was found to be highly variable . There was significant decrease in free amino acid in 10-day-old shoots of Bambusa bamboos, Bambusa tulda, Dendrocalamus asper, Dendrocalamus giganteus, and Dendrocalamus hamiltonii as compared to freshly harvested shoots . Zhang et al.  detected 12 free amino acids in shoots of Phyllostachys praecox. The six amino acids, namely, aspartate, glutamine, glycine, alanine, tyrosine, and histidine were found to be nonessential and remaining 6 amino acids, namely, valine, methionine, isoleucine, leucine, and lysine were essential amino acids. There was substantial decrease in total free essential amino acid (TFEAA) and total free amino acid (TFAA) in boiled bamboo shoots by about 38.85% and 38.35%, respectively. This might be due to loss of amino acids to fluid when the samples were heat treated. Xu et al.  evaluated the amino acids components of 9 bamboo species from South Ankyi Province of China using regular methods. The essential amino acids represented 12-49% of total amino acid content of bamboo shoots under study. Chen et al.  examined the amino acid quantity of shoots of Dendrocalamus latiflorus in different salt concentrations during pickling process. The amino acid in pickled bamboo shoots with 8% salt concentration was highly reduced from 16.35 g/100 g fresh weight in fresh form to 6.898 g/100 g fresh weight in pickled shoot.
2.2. Proteins. Bamboo shoots are good source of protein with protein content ranging from 1.49 g/100 g to 4.04 g/100 g fresh weight in fresh bamboo shoots [7, 31]. Sharma et al.  found variation in amount of protein in 9 species of bamboos studied. Pandey and Ojha  observed gradual decrease in protein content in shoots of Bambusa bamboos when shoots were subjected to heat treatment in increase salt concentration. The level of protein was least reported in shoots boiled for 25 minutes in 10% NaCl solution. Nirmala et al.  detected the lowest amount of protein in canned shoots (1.980 g/100 g fresh weight) as compared to fermented (2.005 g/100 g fresh weight), 10-day-old emerged shoots (2.230 g/100 g fresh weight) and freshly harvested shoots (3.863 g/100 g fresh weight) of Dendrocalamus giganteus. However Devi and Singh  found enhancement of protein content in fermented shoots from 3.1% to 7.1% and 8.1% on the 3rd and 5th day of fermentation process, respectively. Zhang et al.  reported decrease in level of protein in bamboo shoots in Dendrocalamus asper and Dendrocalamus strictus with time. The protein content of 8day-old bamboo shoot of Dendrocalamus asper (1.21 g/100 g fresh weight) and Dendrocalamus strictus (1.91 g/100 g fresh weight) reduced significantly in another 10 days as observed in 18-day-old shoots of Dendrocalamus asper (0.86 g/100 g fresh weight). Another observation made by Nirmala et al.  indicated the decrease in protein level in 10-day-old bamboo shoots when compared to freshly harvested shoots of Bambusa bamboos, Bambusa tulda, Dendrocalamus asper, Dendrocalamus giganteus, and Dendrocalamus hamiltonii.
2.3. Minerals. Bamboo shoots are endowed with rich quantities of useful minerals such as potassium, phosphorus, sodium, calcium, magnesium, and iron. Minerals are required for the proper functioning of many useful metabolic activities of our body. Bhargava et al.  identified the highest content of potassium (1400 mg/100 g fresh weight) in Bambusa arundinaria while the least amount (20 mg/100 g fresh weight) was detected in Melocanna baccifera. Bhatt et al.  reported low amount of potassium (20 mg/100 g fresh weight) in Dendrocalamus longispathus, Dendrocalamus hookeri, Dendrocalamus sikkimensis, and Bambusa tulda. Nirmala et al.  observed very slight reduction in potassium content in 10-day-old shoots of Bambusa bamboos, Bambusa tulda, Dendrocalamus asper, and Dendrocalamus giganteus except for Dendrocalamus hamiltonii which had potassium amount of fresh shoot (416 mg/100 g fresh weight) reduced to almost half (210 mg/100 g fresh weight). Feleke  reported high amount of potassium in bamboo shoots of O. abyssinica collected from Assosa (6.63%), Dhidhessa (7.02%), and Pawe (7.15%) regions of Ethiopia. The level of potassium in shoots of O. Abyssinica was higher than the popular vegetables like Amaranthus spinosus, Hibiscus species, and Solanum macrocarpon. The daily recommended dose of potassium is 2.0 to 5.5 g/d  and it confers protection to human heart by maintaining normal BP and stable heartbeat of an individual. The iron requirement by women at pregnancy and during the nursing of child is very high . Regular consumption of iron rich bamboo shoots will provide the necessary iron requirement of the individual. Pandey and Ojha  examined changes in mineral content of shoots of Bambusa bamboos, Bambusa tulda, Dendrocalamus asper, and Dendrocalamus strictus by subjecting to differential treatment of salt concentration and boiling at different time durations. The minerals, namely, potassium, sodium, phosphorus, calcium, and magnesium present in the fresh bamboo shoot did not show significant change after treatments. However level of sodium enhanced prominently from 0.07 mg/100 g fresh weight in fresh shoot to 1.15 mg/100 g fresh weight in shoots boiled in 10% NaCl for 25 minutes. There is slight variation in presence of traces elements such as cadmium, cobalt, manganese, nickel, and selenium in freshly harvested shoots, fermented and nonsalted canned shoots in Dendrocalamus giganteus. But reduction in zinc content was observed in canned and fermented shoots as compared to fresh shoots .
2.4. Carbohydrate. The level of carbohydrates present in bamboo shoots is reported to be high and its content in edible shoots of Bambusa nutans, Bambusa vulgaris, Dendrocalamus strictus, and Dendrocalamus asper was found at 3.3%, 3.4%, 0.6%, and 2.9%, respectively . There was significant increase in the amount of carbohydrate in bamboo shoots after subjecting them to boiling process. The rise in carbohydrate may be due to hydrolysis of complex polysaccharides into single monosaccharide sugar units. The carbohydrate content decreased when bamboo shoots from Bambusa bamboos, Bambusa tulda, Dendrocalamus asper, and Bambusa strictus were boiled in solution with different salt concentrations . The presence of salt in solution might have played a role in reducing the carbohydrate level in shoot by enhancing the hydrolysis of carbohydrate during boiling. Pandey and Ojha  also reported a rise in carbohydrate level with increase in age of bamboo shoots. The carbohydrate content in two-day-old shoot (1.42 g/100 g fresh weight) increased to 2.46 g/100 g fresh weight after 16 days. However, Nirmala et al.  reported reduction of carbohydrate with increase in age of bamboo as 10-day-old shoot (2.30 g/100 g fresh weight) had lesser carbohydrate as compared to freshly harvested shoots (5.42 g/100 g fresh weight). Carbohydrate in fermented shoot (1.504 g/100 g fresh weight) was decreased when compared to carbohydrate content of fresh shoots of Dendrocalamus giganteus (5.103 g/100 g fresh weight) . Similar observation of carbohydrate reduction was reported by Devi and Singh  in soidon, produced from fermented shoots of Phyllostachys humilis.
2.5. Fat. Bamboos shoots are known to have very less amount of fats and its low content makes them an ideal candidate for providing healthy nutrition to people with diabetic and cardio thoracic diseases. Kumbhare and Bhargava  reported very low amount of fat (0.1 g/100 g fresh weight) in shoots of Dendrocalamus strictus. Nirmala et al.  also revealed lowest fat content in nonsalted canned shoots (0.250 g/100 g fresh weight) as compared to fermented (0.315 g/100 g fresh weight) and freshly harvested shoots (0.387 g/100 g fresh weight) of Dendrocalamus giganteus. The level of fat was significantly increased almost 3- to 4-fold in older shoots of 10 days as compared to juvenile shoots of Bambusa bamboos, Bambusa tulda, Dendrocalamus asper, Dendrocalamus giganteus, and Dendrocalamus hamiltonii . Bhatt et al.  reported maximum fat level (1.00 g/100 g fresh weight) in Bambusa nutans while the least was observed in Bambusa polymorpha, Bambusa vulgaris, and Dendrocalamus strictus. Kozukue and Kozukue  detected presence of fatty acids like palmitic, linoleic, and linolenic acid in bamboo shoots. The level of fat was reduced in boiled and steamed bamboo shoots of Phyllostachys praecox except for stirred fried bamboo shoots which had total gain of fat from 0.21 g/100 g fresh weight in raw shoot to 1.32 g/100 g fresh weight in stirred food .
2.6. Fibre. The dietary fibres possess number of health benefits as they control blood pressure, hypertension, and obesity and also protect body from coronary diseases and potential carcinogens . The consumption of fibre-rich diets helps in reducing the unwanted bad cholesterols (low density lipoprotein and very low density lipoprotein) in the blood, lowering insulin demand, keeping the digestive track healthy, and improving laxative property [39-41]. The intake bamboo shoots on regular basis improves the lipid profile and bowel movement in young healthy women [8, 42]. Bhatt et al.  reported maximum presence of crude fibre (35.5%) in Melocanna baccifera, while Sharma et al.  observed variation in total fibre, cellulose, hemicellulose, and lignin content in bamboo shoots of Bambusa arundinaria, Bambusa polymorpha, Bambusa tulda, Dendrocalamus vulgaris, Dendrocalamus calostachyus, Dendrocalamus giganteus, Dendrocalamus membranaceus, and Dendrocalamus strictus. The amount of dietary fibre increased by around 2fold in 10-dayold shoots as compared to fresh shoots of Bambusa bamboos, Bambusa tulda, Dendrocalamus asper, Dendrocalamus giganteus, and Dendrocalamus hamiltonii . The fibre content in bamboo shoot after boiling was not decreased significantly . However dietary fibre components such as NDF, ADF, lignin, hemicellulose, and cellulose increased in fermented shoots of Dendrocalamus giganteus when compared to freshly harvested shoots . The presence of high fibre in bamboo shoots helps in reducing the fat and cholesterol level of blood thereby making them one of popular health foods among individual with modern lifestyle disease. Pandey and Ojha  reported the increase in dietary fibre in the shoots of Dendrocalamus asper, Dendrocalamus strictus, and Bambusa tulda with increase in age of bamboo shoots. The comparative analysis of nutrient composition of fresh, boiled, and fermented bamboo shoots of some edible bamboo species is described in Table 3.
2.7. Phytosterol. Phytosterols with its structure similar to cholesterol are extensively found in plants and their presence in fresh or fermented bamboo shoots is very prominent [43, 44]. The importance of phytosterol in maintaining quality life is well documented by several workers [45-47]. Lu et al.  evaluated phytosterol content in bamboo shoots of Pleioblastus amarus, Pleioblastus pubescens, Dendrocalamus latiflorus, and Pleioblastus praecox using ultraperformance liquid chromatography. They detected presence of higher level of ^sitosterol as compared to other sterols like campesterol and stigmasterol. Phytosterol-rich diets help in reduction of colon, breast, and prostate cancer [49-51]. The progression of tumour growth is inhibited by interfering the cell cycle, apoptosis, and tumour metastasis. The cholesterol level in blood is reduced as presence of phytosterol inhibits the absorption of dietary cholesterol and cholesterol esterification in intestinal mucosa. Lachance and He  identified [beta]-sitosterol, campesterol, and stigmasterol as the major sterols present in bamboo shoots. Sarangthem and Singh  reported sitosterol as the most abundantly available phytosterol in bamboo shoots. A good amount of phytosterol which can be extracted from freshly harvested bamboo shoots may be effectively employed for the production of steroidal drugs. This will ease the pressure on Dioscorea and Solanum species as primary natural source of steroidal drugs.
2.8. Phenols. Phenolic compounds present in plants are important bioactive compounds as they exhibit strong natural antioxidative and anti-inflammatory properties and sometimes antimicrobial activities as well [54-57]. Bamboo leaves possess antioxidant capacity because of high presence of phenolic compounds [57-59]. Park and John  identified eight phenolic acids in bamboo shoots of Phyllostachys pubescence of which protocatechuic acid, phydroxybenzoic acid, and syringic acid were found to be most abundant. The extracts of stems and leaves of Phyllostachys spp. exhibited strong antibacterial activities . Velioglu et al.  reported that the correlation between the antioxidant property of the plant and phenolic compound content was statistically significant. Zhang et al.  studied changes in amount of phenolic compounds when fresh bamboo shoots were boiled, steamed, and stir fried. The total phenolic content in both boiled and stirs fried samples reduced slightly compared to fresh shoots. But there was increase in the level of phenolic compounds in steamed bamboo shoot. The decrease in amount of phenolic compounds in boiled or stir fried shoot samples may be due to decomposition of phenolic compounds during the heat treatment. However, Yamaguchi et al.  opined that heat treatment may lead to the inactivation of existing phenolic oxidases which were responsible for decomposition of polyphenols. The higher level of total phenolic compounds and increase in antioxidant activity were positively correlated . Pandey and Ojha  reported variation in phenolic compound present in bamboo shoots of Dendrocalamus asper, Dendrocalamus strictus, and Bambusa tulda at different optimum harvesting times. Gallic acid concentration increased in Dendrocalamus asper and so did the caffeic acid in all bamboo species with increase in age of the shoots. The level of vanillic acid in Bambusa tulda was decreased but its concentration increased in both Dendrocalamus asper (from 0.009 g/100g fresh weight to 1.262 g/100 g fresh weight) and Dendrocalamus strictus (from 0.273 g/100g fresh weight to 2.563 g/100 g fresh weight). Pandey and Ojha  also observed decrease in total phenol content in shoots of Bambusa bamboos, Bambusa tulda, and Dendrocalamus asper when shoots were boiled in higher salt concentration for longer duration.
3. Taxiphyllin in Bamboo Shoots
Bamboo shoots contain varying amount of cyanogen glycosides called taxiphyllin [65-68]. The [beta]-glycosidase which is released in disrupted bamboo shoot tissues acts on taxiphyllin to produce harmful hydrogen cyanide whose level should not exceed the toxic level in humans . The harmful hydrogen cyanide should be removed if shoots are to be used for human consumption . The generation of cyanide in bamboo shoots and its possible harmful effects on human health in its toxic level are represented in Figure 1. Many investigators have worked on different bamboo species to determine the cyanogen contents [65, 67, 71]. Jones  reported variation in cyanide (HCN) content in different parts of the bamboo plant and also with different species of bamboos. Bamboo shoots of most edible species contain high amount of cyanogen glycoside with its maximum concentration found at the shoot tip. Haque and Bradbury  observed total cyanide content in bamboo shoots of Bambusa arundinacea (1010 ppm) to be much higher than other plants like flax seed meal (390 ppm), cassava root (27 ppm), sorghum leaf (750 ppm), apricot stone (785 ppm), and giant taro leaf (29 ppm). Unlike linamarin and lotaustralin which are the cyanogenic glycosides found in cassava plants, taxiphyllin in bamboo shoots is highly unstable and is easily decomposed when treated with boiling water. Bamboo shoot with high toxic level of cyanogenic compound can be made totally edible when detoxify by boiling in water for around 2 hours. However, consumption of improperly prepared or processed bamboo shoots may produce symptoms like rapid respiration, drop in blood pressure, dizziness, stomach pains, headache, vomiting convulsion, and coma . Hydrogen cyanide interferes in proper functioning of cytochrome oxidase inhibiting normal cellular respiration. According to FSANZ report, the HCN present in concentration of 0.5-3.5mg/Kg body weight is considered as lethal which may cause serious health damage leading to death. HCN is a respiratory poison which when present in high concentration may lead to serious health predicament to individual concerned. Pramod Kumar et al.  reported a case of cyanide poisoning in JSS Hospital, Mysore, India, when a 14-year-old female patient was brought to the Hospital in unconscious state with a history of consumption of bamboo shoot extract (juice). The patient showed the symptoms of convulsion, vomiting, respiratory distress, and loss of consciousness but regained consciousness two days after proper medical treatment. This case might be an isolated one as there have not been any reports of extreme cyanide poisoning because of bamboo shoot consumption as fresh or fermented shoots are presoaked and boiled in water during the preparation of most bamboo based ethnic dishes. Some tribal people in Northeast India consume aqueous exudates of fermented bamboo shoots apart from normal fresh and fermented shoots as one of the important condiments providing ethnic flavour to various traditional dishes. Incidence of stomach ailments and other mild health related problems are evident when improperly processed bamboo shoots are consumed. Shoot processing methods presently employed by locals are largely crude and traditional and lack scientific approaches for generation of safe bamboo foods. Devising scientific processing methods to reduce cyanogenic content and also assessing the toxicity of processed bamboo foods are essential to avoid acute cyanide poisoning during consumption. Various methods are being adopted to lower cyanide content and remove bitterness from either fresh or fermented shoots for safe and healthy consumption. Cooking at around 100[degrees]C for 48 hours effectively eliminates 97% of cyanide content of the shoot . Other simple procedures include slicing of tender shoots into thin slices, drying, and boiling in salt water followed by draining. The fresh shoots must be adequately processed before consumption to remove the toxic and bitter components [77, 78] that showed reduction of cyanide content in fresh bamboo shoot when they were subjected to NaCl treatment. The hydrocyanic acid content of bamboo shoot can be significantly lowered during the time of bamboo shoot steaming process . Pandey and Ojha  observed that bamboo shoots processed by boiling in water with varied concentration of NaCl for different time intervals produced maximal cyanide removal with minimum nutrient loss. The cyanogen in shoots of Bambusa tulda and Dendrocalamus asper was significantly lowered without much reduction in the content of carbohydrates, proteins, total phenol, potassium, phosphorus, and sodium when shoots were boiled for 25 minutes in 1%, 5%, and 10% NaCl solution. Wongsakpairod  showed that HCN can be removed by exposing bamboo shoots to superheated steam as taxiphyllin decomposed at over 116[degrees]C. Bhardwaj et al.  also reported the use of banana leaves by Adi tribe of Arunachal Pradesh for removing toxic cyanogen during bamboo fermentation. The bamboo shoots were pressed hard under big stones and kept for 3-4 months to lower down the bitter taste of fermented bamboo shoots. Choudhury et al.  identified the importance of devising proper shoot processing methods to generate healthy improved bamboo shoot product with longer shelf life.
4. Different Traditional Edible Forms of Bamboo Shoot
The emerging tender shoots must be collected at appropriate time of growing season when young shoots attend suitable height and development. The best edible shoots for consumption are obtained in middle of growing season as shoots harvested during the beginning or end of growing season tend to be either weaker or overdeveloped. The bamboo shoots may be further processed for consumption in fresh or fermented forms after harvest. They are popular food items and are used to prepare different traditional dishes in many Asian countries like China, Korea, Japan, Thailand and Taiwan. Gulai rebung which is made from bamboo shoots with thick coconut milk is widely consumed in Indonesia. People of Philippines make local cuisine called labong from bamboo shoots, coconut milk, and chilies . A popular local dish called Alui tama is consumed in Nepal which is made by cooking the fermented bamboo shoots with potatoes. The young fresh bamboo shoots which are called tusa in hills of Nepal and fermented ones identified as tama are considered as important ethnic food items of the region . The steamed ground pork patty with finely diced bamboo shoots sprinkled with soy sauce on the top is consumed as one of the most popular Chinese dishes. The freshly harvested bamboo shoots after the removal of hard sheaths are cleaned with water and shredded in small slices. The shoot pieces are treated with plain water for 2 to 3 hours or boiled for 1 and half hours to remove the acridity. In some countries like Thailand and Vietnam, the finely chopped bamboos may be directly consumed as salad after water treatment. The bamboo shoot pieces after boiling are salted slightly for 8-10 minutes and consumed in Australia and New Zealand . Popular Thai curry called ma khua proh is made by cooking bamboo shoots with white pumpkin and pea aubergine. Dom jud nomai is another highly sought after Thai soup made from thinly sliced bamboo shoots with pork ribs mixed with salt, garlic, and pepper. The Vietnamese broth called Sup bun mangga which is a noodle soup made with chicken and fresh bamboo shoots is usually taken as breakfast. The freshly collected bamboo shoots can be canned after proper processing. China, Taiwan, and Thailand are the leading countries in the export of canned bamboos to other countries like USA, UK, Australia, Singapore, Canada, and New Zealand . There are reports of using bamboo shoots as food in other parts of India like Orissa, Gujarat, and Western Ghats regions of Karnataka . The Kandha tribe of Western India prepares kardi a traditional bamboo based food by soacking shredded pieces of shoots in water for a day in order to remove bitterness before cooking . Bal et al.  while undertaking a survey in five villages of Orissa, India, observed that bamboo shoots are consumed by locals after proper boiling in water. The processing of fresh shoots is performed by boiling at different temperature conditions and duration to remove the acrid taste and toxic elements. They are used in the preparation of pickles, snacks, papads, and other fried food stuffs in remote and hilly areas of Western Ghats .
5. Bamboo Based Traditional Foods of North-East India
The Northeast India comprising of eight states, namely, Assam, Manipur, Meghalaya, Mizoram, Nagaland, Sikkim, Arunachal Pradesh, and Tripura is located between 21[degrees]-30[degrees]N latitude and 85[degrees]-98[degrees]E longitude. It covers an area of around 18.4 million hectares and is physiographical categorized into the Eastern Himalayas, Northeast hills, Brahmaputra, and Barak valley. This region with different ethnic communities and diverse cultures and religions is considered as a treasure house of bamboos contributing more than 66% of total bamboos resources available in India . About 16 edible bamboo species are reported in Northeast India  and some of the important edible bamboo species are Arundinaria callosa, Bambusa nutans, Bambusapallida, Bambusa polymorpha, Bambusa tulda, Dendrocalamus hamiltonii, Dendrocalamus giganteus, Dendrocalamus brandisii, Melocanna baccifera, Melocanna bambusoides, Dendrocalamus hookeri, Dendrocalamus sikkimensis, Dendrocalamus strictus, and Phyllostachys manni. The bamboo shoots form an integral part of many of popular traditional cuisines and the locals consumed either fresh or fermented bamboo shoots in the form of various local delicacies.
5.1. Fresh Bamboo Shoots. The indigenous people of Northeast India take fresh shoots as one of the popular food items. The possible uses of fresh bamboo shoots for preparation of several traditional dishes are depicted in Figure 2. Fresh bamboo shoots are consumed in Manipur as ushoi which is produced by chopping the inner soft portion of shoot into thin slices after peeling off the outer sheath and treating them in water for 3-4 hours (Figures 3(a), 3(b), and 3(c)). It is primarily used in the preparation of number of favourite ethnic dishes and can be preserved for off-season by drying under sun after excess water is drained off. Another bamboo species popularly consumed fresh is Arundinaria callosa whose average size slender shoots with protective sheaths are sold in market during the harvesting season. The shoots after peeling off the hard sheaths are sliced into pieces which are either boiled for around 1 hour or shocked in water for 3-4 hours to remove bitterness of shoot. The properly processed shoots are used to make variety of traditional local chutney called iromba and also cook as vegetable with fishes and meat. In Arunachal Pradesh, young bamboo shoots are boiled and cut into pieces and used as vegetable for preparation of traditional dish called kupe . Shoots obtained from Bambusa balcooa, Bambusa nutans, and Dendrocalamus strictus are slightly bitter and require proper processing by either steaming or boiling briefly and changing the water intermittingly till the bitterness is lost . In states like Meghalaya, Mizoram, and Sikkim, the fresh young shoots of Melocanna baccifera, Dendrocalamus hamiltonii, Bambusa balcooa, and Chimonobambusa hookeriana are consumed either boiled with other leafy vegetables or fried with other nonvegetable components .
5.2. Fermented Bamboo Shoot. The bamboo shoots in fermented form are consumed as one of favourite traditional foods by different ethnic communities. Some of the important fermented bamboo shoot products familiar with locals are soibum, soidon, soijim, bastanga pani, rep, eup, mesu, and so forth. Soibum is one of the most popular fermented foods of Manipur normally available in almost all local vegetable markets (Figure 3(d)). It is made from tender shoots of Dendrocalamus hamiltonii, Dendrocalamus giganteus, Bambusa tulda, Bambusa balcooa, and Bambusa pallid and is widely used in preparation of special delicacies. Jeyaram et al.  reported two approaches of soibum production normally practised in the region. The more popular kwatha or noney method uses traditionally designed chamber lined with Colocasia leaves or polythene sheets and packed with thinly sliced bamboo shoots. While the Andro type involves the use of big earthen pot filled partly with shredded bamboo shoots, the quantity of which is increased by external addition as fermentation proceeds. The liquid portion is not removed as the fermentation continues for 6-8 months. A simpler method practised in Bishenpur is use of a large plastic tub which contains finely chopped shoots with enough water to submerge them; the shoots are kept in aerobic condition for 15-20 days before being removed and packed in closed plastic bags for 2-3 months. The liquid remnants can be repeatedly used as starter culture for next round of soibum production as it shortens the fermentation process by 6-7 days. Giri and Janmejay  indicated the increase in quality of soibum with increase in incubation period. Tankhul tribes use local bamboo variety called ngathan to produce dried soibum which looks like noodles with twisted appearances. In Arunachal Pradesh, Nishi tribes consume ekung a fermented bamboo shoot product similar to soibum. Apatani tribes of the same region prepare hirring by fermenting the sliced tender upper portion of shoots of Dendrocalamus giganteus, Phyllostachys assamica and Bambusa tulda. The delicious curries produced by cooking hirring together with meat, fish, or vegetables are favourites among locals . Barman community of Tripura prepares traditional dish called godhak which is made by mixing fermented bamboo shoots along with pseudobulbs of banana, dry fishes, salt, chili, and garlic . Mesu is another fermented shoot product which is a favourite among the people of Sikkim and Darjeeling as locally made pickle. Naga tribes of Nagaland use bamboo juice extracted from fermented shoots as integral component of daily cuisine as it adds ethnic flavour and aroma to the curries.
6. Market Potential of Bamboo Shoot in Northeast India
The value of international bamboo market is estimated to be around $10 billion . The total revenue from bamboo shoots is about $1.2 billion while other bamboo based products accounts for around $3 billion . Bamboo shoot is consumed worldwide and annual world bamboo consumption is presently over 2 million tonnes . The intake of bamboo shoot as popular food is mostly found in Asian countries like China, Thailand, Korea, Taiwan, and Japan. Bamboo shoots occupy the second position in annual vegetable production volume in Taiwan with Dendrocalamus latiflorus and Bambusa oldhamii as the two most important edible bamboos consumed in the country. China and Thailand are considered as the two most dominant players in the international bamboo market. China is the largest exporter of edible shoot earning around $4 million annually with Thailand following closely at second position . The trade value of bamboo shoots is found to be highest in all bamboo commodities being exported from China between 1998 and 2002. China exports bamboo shoots mainly to Japan and USA accounting approximately about 74% and 11%, respectively, of total bamboo exports. Japan imports 134000 tonnes of bamboo shoots per annum amounting to 45% of world total import, while USA stands distant second by importing around 44000 tonnes annually . The import of bamboo shoots in Australia in 1992 was estimated at 1,350 tonnes accounting to about $5.0 million value . India has rich bamboo genetic resources and is the second largest bamboo producing nation in the world next to China with annual production of 32.3 million tonnes [103,104]. However, domestic bamboo shoot industry of the country is at nascent stage which is estimated at around $0.8 million. The general acceptability of bamboo shoot as popular food among the masses is low due to its pungent taste and strong odour as well as the easy availability of lower priced vegetables as an alternative. As largely bamboo shoots are consumed traditionally by ethnic people, the popularity of the food is confined to only few tribes and communities and the taste has to be developed through frequent exposure. In India, bamboo shoots are consumed mainly in Northeast India where they are integral part of many popular tribal cuisines. The prospect of bamboo shoot based industry especially in the region is tremendous as it harbours more than 66% of total bamboo population of India. Despite being a rich repository of bamboos, this region produces only 5685 tonnes of bamboo shoots annually . Singh  reported a gross annual income of $1.3 million in 8 Northeastern states of India in bamboo shoot trade which included marketing of fresh and processed bamboo shoots. The net annual income from bamboo shoot industry is $0.7 million indicating one of the potentially profitable business avenues for the region. However, the present market scenario of bamboo shoot is not very promising despite its very rich bamboo resources. The production of bamboo shoot is mainly for domestic and local consumptions and it has not been pursued at the industrial scale. There are very few canning factories which can totally absorb production of perishable bamboo shoot products. There are only 3-4 small processing units in entire Northeast region each located at Dimapur, Nagaland (900 tonnes/year), Jorhat (200 tonnes/year), and Bongaigoan, Assam (300 tonnes/year). The volume of bamboo shoot export outside Northeast region is very less and majority of locally produced bamboo shoot products find their way to local markets only. In order to tap the highly potential market, more efforts need to be made with outmost sincerity to exploit the rich bamboo resource by encouraging local bamboo shoot production at the industrial scale using proper scientific methods. Nowadays with increased consciousness for safe and healthy foods and the people's preference for bamboo based Chinese and Oriental cuisines, the prospect of bamboo shoot in local and international market is tremendous. Moreover, demand for bamboo shoot has increased several folds as many speciality restaurants, food outlets, and 5 star hotels in towns and metropolitan cities of India serve bamboo based continental and oriental foods. The domestic consumption of bamboo shoot in Japan, Korea, and other Asian countries is also increasing and the demand for import is becoming more as the bamboo shoot production in these countries has declined due to short production season. The market potential of bamboo in India is estimated to be around $6 million by 2015 and the Northeast region being the largest contributor of bamboos in India, there is an ample opportunity to step up its own bamboo shoot production to not only address its own local requirement but also exploit the export avenues especially the highly potential and profitable destinations like Japan, Korea, Taiwan, and other Asiatic countries.
7. Bamboo Micropropagation: A Biotechnological Approach to Effective Conservation
The bamboos are largely overexploited because of their enormous utility for different purposes besides being used as popular ethnic food . There is alarming reduction of bamboo natural resources due to their increase utilization for industrial and domestic purposes and also widespread habit destruction . Propagation of bamboos through conventional methods by using seeds, rhizome division, and culm cutting do not produce desired result because of nonavailability of adequate planting materials, problems in handling of large size propagules, unpredicted flowering cycle, and short viability of the seeds . As bamboo propagation through classical methods cannot generate enough bamboos resources, there is a necessity of adopting new methods to increase bamboo production at much larger scale . Micropropagation of bamboos through tissue culture provides an excellent opportunity as an alternative biotechnological tool to insufficient and inefficient classical propagation methods for rapidly propagating several rare and edible bamboos in large numbers . Several workers have successfully micropropagated bamboos using different explants like mature embryos, rhizomes, nodal segments, and inflorescences [111-117]. The selection of appropriate explants for culture initiation and further regeneration is paramount to success of bamboo tissue culture. The collection of explant in winter produced less contamination as compared to explants collected during rainy season. The surface disinfection of selected bamboo explants can be effectively performed using either mercuric chloride (0.11%) or sodium hypochlorite (1-2%) along with treatment of soft detergent solution . Mishra et al.  administered 0.05% mercuric chloride for nodal explants collected during winter time while 0.1% mercuric chloride treatment was given to explants harvested during summer season. The use of 0.1-0.2% mercuric chloride in rainy season enhanced aseptic culture establishment but inhibited bud break due to its toxicity to explant tissues. Fungicides (bivastin 1%) and bacteriomycin (streptomycin 0.2%) may also be employed if required to control fungal and bacterial contaminations of selected nodal explants. Bud break and sprouting of buds from nodal explant is strongly influenced by genotype, juvenility of explant tissues, and its physiological state, season of explant collection, and culture initiation [119-121]. Sharma and Sarma  reported axillary bud breaking 3 weeks in Bambusa balcooa when nodal explants were transferred on BAP (6-benzylaminopurine) and IBA (indole-3-butyric acid) supplemented agar solidified Murashige and Skoog  medium. However, sprouting of axillary was also noticed in 4 weeks on phytagel solidified MS medium without any growth regulators . The bud break and bud sprouting were recorded in just 6-7 days when the nodal explants of M. baccifera were inoculated in liquid MS medium enriched with 14 mg/L Kn (kinetin) and 2 mg/L BAP. The bud break and sprouting took more time in solid medium with same hormonal combinations. The improved frequency of bud break and shoot multiplication and elongation were also observed by several workers [113,125,126]. The lower growth response of culture in agar gelled nutrient medium may be due to binding of water, absorption of nutrients, and plant growth regulators (PGRs) by solubilised agar which led to reduce utilization of nutrients, PGRs, and other essential constituents by the culture. The frequency of bud break and incidence of bacterial contamination are dependent on season for explants collection. The bud break was found to be low for explants collected during rainy reason due to high bacterial and fungal contamination . The shoot elongation and proliferation after the bud break could be increased and maintained by subculturing at regular interval of 4-5 weeks on MS medium incorporated with different concentrations of growth regulators . Sharma and Sarma  observed stagnant and unhealthy growth of shoot after bud break when subculturing was performed at lower concentration of Kn in Bambusa balcooa. The stunted growth if continues for longer time will ultimately lead to death of culture. Regular subculturing provides optimal and desired level of culture regeneration and multiplication and delay in doing so will produce death of culture due to browning. The phenolic compounds responsible for browning phenomenon in culture can be controlled by frequent subculturing and incorporating ascorbic acid, activated charcoal, or polyvinyl pyrrolidone. Singh et al.  reported significant reduction of browning by supplementing medium with ascorbic acid, while activated charcoal and polyvinyl pyrrolidone did not have any effect on the control of phenolic compounds. Shoot multiplication and elongation were more pronounced with well-developed leaves in M. baccifera and D. hamiltonii when subculturing was done every 15-20 days in MS medium supplemented either with 0.5mg/LNAA (1-naphthaleneacetic acid) and 5mg/L Kn or 2 mg/L Kn, 0.5 mg/L IBA, and 0.3% activated charcoal . Similar observation was reported by Mudoi and Borthakur  in Bambusa balcooa. Prominent shooting response was detected in Bambusa bamboos when elongated axillary shoots from primary culture were transferred to shooting medium incorporated with different concentrations of BAP . The main constraint to successful propagation of bamboos and other woody species is the difficulty in reducing appropriate rooting [132,133]. The use of auxins such as IBA and NAA was reported for effective rooting induction in several bamboo species [134-136]. However, rooting in Pleioblastus pygmaeus was successfully established in basal MS medium without any growth regulators . Incorporation of 5.1 mg/L IBA and 0.01 mg/L BAP in liquid MS medium produced maximum rooting response in Arundinaria callosa Munro . Stout rooting system was observed in 7-10 days when the in vitro rooted shoots were transferred to PGR-free half strength MS medium. Use of additives like choline chloride and coumarine along with auxins enhanced rooting induction in some bamboos [120, 129]. Two steps rooting procedure in bamboos was formulated by Bag et al.  when they used IBA treatment for rooting induction which is followed by transferring the culture to auxin-free media to achieve strong rooting system. The regenerated plantlets with established shoots and roots were washed in running tap water and shifted to soil mixture in a pot for appropriate hardening. The well-rooted plants after proper hardening have survival rate of about 80-85% under polyhouse/net house conditions which can be transplanted to field for effecting ecorestoration in their natural habitats. The use of tissue culture technology can propel the production of bamboos at the scale of more than 500000 bamboo plants per year . This scientific approach of rapid and mass scale propagation of bamboos can effectively restore the already depleted natural bamboo resources. The "ex situ" approach of bamboo conservation may also be adopted by declaring the bamboo dominated forest areas as special gene sanctuary for bamboos. Establishment of "Bambusetum" at suitable places is another approach to effective bamboo conservation at smaller scale. The conservation of bamboos at Cherra and Basa in Arunachal Pradesh is an appropriate example where 35 species and 30 species of bamboos are, respectively, being preserved successfully . The in vitro and ex situ conservation methods if effectively formulated and implemented may help address to a large extent the present acute scenario of population depletion of bamboo species of the region.
8. Conclusions and Future Perspective
Bamboo shoots have immense potential of being used as important health food as they have high content of useful proteins, amino acids, carbohydrates, and many important minerals and vitamins and very low fat. Bamboo shoots are consumed predominantly in Asiatic countries where they form integral part of several traditional cuisines of the region. The usefulness of bamboo shoots as health food is not largely known by general public due to ignorance of their high nutritional values. There is a greater necessity to create awareness among the people about their nutritional health benefits so that they are widely accepted. Bamboos occupy a very significant position in everyday life of indigenous people of Northeast India due to their enormous utility as traditional food, house construction materials, and raw materials for production of useful domestic and other handicraft items. The fresh or fermented bamboo shoots form an indispensable part of number of ethnic dishes. But shoots should be properly processed as they contain high level of toxic cyanogenic glycosides. Using improved shoot processing methods based on scientific approach instead of crude and unhygienic ones will not only reduce toxic cyanogenic compound but also retain the nutritional values. The region being the largest producer ofbamboos in India has a bright prospect for bamboo shoot industry but presently bamboo shoot production is predominantly for fulfilling the local needs. There is a need to increase bamboo processing and packaging units as very few operate actively in the region. Effective marketing strategies should also be formulated to extract maximum profits by making bamboo shoot products available to as many potential and prospective customers inside and outside the country. Intervention of modern micropropagation techniques is also essential to control the falling population of bamboos. The local bamboo shoot industry if properly established will not only help in socioeconomic upliftment of the region but also generate huge income for the country.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
The authors are thankful to SERB (Science & Engineering Research Board), New Delhi, India, for the financial support.
 J. M. O. Scurlock, D. C. Dayton, and B. Hames, "Bamboo: an overlooked biomass resource?" Biomass and Bioenergy, vol. 19, no. 4, pp. 229-244, 2000.
 N. Bystriakova, V. Kapos, I. Lysenko, and C. M. A. Stapleton, "Distribution and conservation status of forest bamboo biodiversity in the Asia-Pacific region," Biodiversity and Conservation, vol. 12, no. 9, pp. 1833-1841, 2003.
 A. Lewington, Plants for People, Oxford University Press, New York, NY, USA, 1990.
 V. V. A. Vatsala, Bamboos in India, NISCAIR, New Delhi, India, 2003.
 J. Bao, "The nutrition and bioactive function of bamboo shoots," Food Nutrition China, vol. 4, pp. 2-3, 2006.
 C. Nirmala, M. L. Sharma, and E. David, "A comparative study of nutrient component of freshly harvested, fermented and canned bamboo shoots of Dendrocalamus giganteus Munro," The Journal of the American Bamboo Society, vol. 21, no. 1, pp. 33-39, 2008.
 N. Chongtham, M. S. Bisht, and S. Haorongbam, "Nutritional properties of bamboo shoots: potential and prospects for utilization as health food," Comprehensive Reviews in Food Science and Food Safety, vol. 10, no. 3, pp. 153-168, 2011.
 B. P. Bhatt, K. Singh, and A. Singh, "Nutritional values of some commercial edible bamboo species of the North Eastern Himalayan region, India," Journal of Bamboo and Rattan, vol. 4, no. 2, pp. 111-124, 2005.
 M. S. Bisht, C. Nirmala, and P. Nongdam, "Bamboo shoot as resource for health food and socio-economic development in North-East India," in Proceedings of the 9th World Bamboo Congress (WBC 12), pp. 393-402, Antwerp, Belgium, April 2012.
 A. Bhargava, V. Kumbhare, A. Srivastava, and A. Sahai, "Bamboo parts and seeds for additional source of nutrition," Journal of Food Science and Technology, vol. 33, no. 2, pp. 145-146,1996.
 V. Kumbhare and A. Bhargava, "Effect of processing on nutritional value of central Indian bamboo shoots. Part I," Journal of Food Science, vol. 44, no. 3, pp. 935-936, 2007.
 Q. T. Shi and K. S. Yang, "Study on the relationship between nutrients in bamboo shoots and human health," in Proceedings of the International Symposium on Industrial Use of Bamboo, pp. 338-346, International Tropical Timber Organization and Chinese Academy, Beijing, China, December 1992.
 K. Visuphaka, "The role of bamboo as a potential food source in Thailand," in Proceedings of the International Bamboo Workshop, pp. 301-303, Recent Research on Bamboos, Hangzhou, China, October 1985.
 N. H. Xia, "Analysis of nutritive constituents of bamboo shoots in Guangdong," Acta Botanica Austro Sinica, vol. 4, pp. 199-206, 1989.
 Y. H. Qiuc, X. G. Shaoc, F. G. Zhang, W. L. Hua, and L. W. Bao, "Analysis of physical behaviors and nutrition constituents of Phyllostachys heteroclada bamboo shoots," Journal Zhejang Forestry College, vol. 16, no. 2, pp. 200-202,1999.
 C. J. Chen, E. F. Qiu, R. Z. Huang, H. Fan, and J. X. Jiang, "Study on the spring shoot nutrient content of Phyllostachys pubescens of different provinces," Journal of Bamboo Research, vol. 18, pp. 6-11, 1999.
 M. L. Sharma, C. Nirmala, and E. David, "Variations in nutrient and nutritional components of juvenile bamboo shoots," Panjab University Research Journal, vol. 54, pp. 101-104, 2004.
 P. Singhal, L. M. Bal, S. Satya, P. Sudhakar, and S. N. Naik, "Bamboo shoots: a novel source of nutrition and medicine," Critical Reviews in Food Science and Nutrition, vol. 53, no. 5, pp. 517-534, 2013.
 K. George, M. G. Noordhoff, and J. Slagan, "Dietary fiber used in the management of hypertension and obesity," Journal of the Science of Food and Cantwell Agriculture, vol. 32, pp. 494-497, 1982.
 J. Anderson and M. F. Strong, "The effect of fiber on nutrition of man," India Journal of Nutrition and Dietetics, vol. 81, pp. 279-285, 1983.
 T. Kalita and U. Dutta, "A comparative study on indigenous usage of bamboo shoot in the health care practices in NE India," The Clarion, vol. 1, no. 2, pp. 130-141, 2012.
 E. J. Park and D. J. John, "Effects of bamboo shoot consumption on lipid profiles and bowel function in healthy young women," Nutrition, vol. 25, no. 7-8, pp. 723-728, 2009.
 J. Meric, S. Rottey, K. Olaussen et al., "Cyclooxygenase-2 as a target for anticancer drug development," Critical Reviews in Oncology/Hematology, vol. 59, no. 1, pp. 51-64, 2006.
 F. G. Qiu, "The recent development of bamboo foods," in Proceedings of the International Symposium on Industrial Use of Bamboo, pp. 333-337, International Tropical Timber Organization and Chinese Academy, Beijing, China, December 1992.
 S. S. Giri and L. S. Janmejay, "Effect of bamboo shoot fermentation and aging on nutritional and sensory qualities of Soibum," Journal of Food Science and Technology, vol. 37, no. 4, pp. 423-426, 2000.
 E. Kozukuen, N. Kozukue, and T. Kurosaki, "Organic acid, sugar and amino acid composition of Bamboo shoots," Journal of Food Science, vol. 48, no. 3, pp. 935-938,1983.
 C. Nirmala, E. David, and M. L. Sharma, "Changes in nutrient components during ageing of emerging juvenile bamboo shoots," International Journal of Food Sciences and Nutrition, vol. 58, no. 8, pp. 612-618, 2007
 J. Zhang, R. Ji, Y. Hu, J. Chen, and X. Ye, "Effect of three cooking methods on nutrient components and antioxidant capacities of bamboo shoot (Phyllostachys praecox C.D. Chu et C.S. Chao)," Journal of Zhejiang University SCIENCE B. Biomedicine & Biotechnology, vol. 12, no. 9, pp. 752-759, 2011.
 S. Xu, C. A. O. Wan-You, and Q. Y. Song, "Analysis and evaluation of protein and amino acid nutritional component of different species of bamboo shoots," Journal of Food Science, vol. 26, no. 7, pp. 222-227, 2005.
 G. Chen, L. Wang, and Z. J. Zheng, "Effect of salt concentration on quality of Bamboo shoots during pickling," Food Science, vol. 34, no. 15, pp. 48-52, 2013.
 M. Sundriyal and R. C. Sundriyal, "Wild edible plants of the Sikkim Himalaya: nutritive values of selected species," Economic Botany, vol. 55, no. 3, pp. 377-390, 2001.
 A. K. Pandey and V. Ojha, "Precooking processing of bamboo shoots for removal of anti-nutrients," Journal of Food Science and Technology, vol. 51, no. 1, pp. 43-50, 2011.
 S. P. Devi and H. T. Singh, "Studies on the chemical and nutritional changes of bamboo shoots during fermentation," Journal of Food Science and Technology, vol. 23, no. 6, pp. 338-339, 1986.
 S. Feleke, "Site factor on nutritional content of Arundinaria alpine and Oxytenanthera abyssinica bamboo shoots in Ethiopia," Journal of Horticulture and Forestry, vol. 5, no. 9, pp. 115-121, 2013.
 H. D. Belitz and W. Grosch, Food Chemistry, Springer, New York, NY, USA, 2nd edition, 1999.
 H. Tapiero, L. Gate, and K. D. Tew, "Iron: deficiencies and requirements," Biomedicine and Pharmacotherapy, vol. 55, no. 6, pp. 324-332, 2001.
 A. K. Pandey and V. Ojha, "Standardization of harvesting age of bamboo shoots with respect to nutritional and anti-nutritional components," Journal of Forestry Research, vol. 24, no. 1, pp. 83-90, 2013.
 E. Kozukue and N. Kozukue, "Lipid content and fatty acid composition in bamboo shoots," Journal of Food Science, vol. 46, no. 3, pp. 751-755, 1981.
 L. Brown, B. Rosner, W. W. Willett, and F. M. Sacks, "Cholesterol-lowering effects of dietary fiber: a meta-analysis," The American Journal of Clinical Nutrition, vol. 69, no. 1, pp. 30-42,1999.
 N. C. Howarth, E. Saltzman, and S. B. Roberts, "Dietary fiber and weight regulation," Nutrition Reviews, vol. 59, no. 5,pp. 129-139, 2001.
 Y. Park, D. J. Hunter, D. Spiegelman et al., "Dietary fiber intake and risk of colorectal cancer," The Journal of the American Medical Association, vol. 294, no. 22, pp. 2849-2857, 2005.
 E. J. Park and D. Y. John, "Effects of bamboo shoot consumption on lipid profiles and bowel function in healthy young women," Nutrition, vol. 25, no. 7-8, pp. 723-728, 2009.
 R. C. Srivastava, "Bamboo: new raw materials for phytosterols," Current Science, vol. 59, no. 24, pp. 1333-1334, 1990.
 T. A. Miettinen and H. Gylling, "Non-nutritive bioactive constituents of plants: phytosterols," International Journal for Vitamin and Nutrition Research, vol. 73, no. 2, pp. 127-134,2003.
 D. Kritchevsky and S. C. Chen, "Phytosterols-health benefits and potential concerns: a review," Nutrition Research, vol. 25, no. 5, pp. 413-428, 2005.
 K. M. Phillips, D. M. Ruggio, and M. Ashraf-Khorassani, "Phytosterol composition of nuts and seeds commonly consumed in the United States," Journal of Agricultural and Food Chemistry, vol. 53, no. 24, pp. 9436-9445, 2005.
 R. E. Ostlund Jr., "Phytosterols, cholesterol absorption and healthy diets," Lipids, vol. 42, no. 1, pp. 41-45, 2007
 B. Y. Lu, J. F. Bao, L. Shan, and Y. Zhang, "Technology for supercritical C[O.sub.2] extraction of bamboo shoot oil and components of product," Transactions of the Chinese Society of Agricultural Engineering, vol. 25, no. 8, pp. 312-316, 2009.
 J. Choi, E. Lee, H. Lee et al., "Identification of campesterol from Chrysanthemum coronarium L. and its antiangiogenic activities," Phytotherapy Research, vol. 21, no. 10, pp. 954-959, 2007.
 P. G. Bradford and A. B. Awad, "Phytosterols as anticancer compounds," Molecular Nutrition and Food Research, vol. 51, no. 2, pp. 161-170, 2007.
 T. A. Woyengo, V. R. Ramprasath, and P. J. H. Jones, "Anticancer effects of phytosterols," European Journal of Clinical Nutrition, vol. 63, no. 7, pp. 813-820, 2009.
 P. A. Lachance and Y. H. He, "Hypocholesterolemic composition from bamboo shoots," PCT International Patent PCT/US98/12556,1998.
 K. Sarangthem and T. N. Singh, "Transformation of fermented bamboo (Dendrocalamus asper) shoots into phytosterols by microorganisms," Journal of Food Science and Technology, vol. 40, pp. 622-625, 2003.
 A. E. Rotelli, T. Guardia, A. O. Juarez, N. E. de la Rocha, and L. E. Pelzer, "Comparative study of flavonoids in experimental models of inflammation," Pharmacological Research, vol. 48, no. 6, pp. 601-606, 2003.
 R. Puupponen-Pimia, L. Nohynek, S. Hartmann-Schmidlin et al., "Berry phenolics selectively inhibit the growth of intestinal pathogens," Journal of Applied Microbiology, vol. 98, no. 4, pp. 991-1000, 2005.
 A. M. Lehane and K. J. Saliba, "Common dietary flavonoids inhibit the growth of the intraerythrocytic malaria parasite," BMC Research Notes, vol. 1, article 26, 2008.
 G. Oboh and A. O. Ademosun, "Characterization of the antioxidant properties of phenolic extracts from some citrus peels," Journal of Food Science and Technology, vol. 49, no. 6, pp. 729-736, 2012.
 C. A. Rice-Evans, N. J. Miller, and G. Paganga, "Antioxidant properties of phenolic compounds," Trends in Plant Science, vol. 2, no. 4, pp. 152-159,1997.
 B. Lu, X. Wu, X. Tie, Y. Zhang, and Y. Zhang, "Toxicology and safety of anti-oxidant of bamboo leaves. Part 1: acute and subchronic toxicity studies on anti-oxidant of bamboo leaves," Food and Chemical Toxicology, vol. 43, no. 5, pp. 783-792,2005.
 E. J. Park and D. Y. John, "The antioxidant, angiotensin converting enzyme inhibition activity, and phenolic compounds of bamboo shoot extracts," Food Science and Technology, vol. 43, no. 4, pp. 655-659, 2010.
 N. K. Kim, S. H. Cho, S. D. Lee, J. S. Ryu, and K. H. Shim, "Functional properties and antimicrobial activity of bamboo (Phyllostachys spp.) extracts," Korean Journal of Food Processer, vol. 8, pp. 475-480, 2001.
 Y. S. Velioglu, G. Mazza, L. Gao, and B. D. Oomah, "Antioxidant activity and total phenolic in selected fruits, vegetables and grain products," Journal of Agricultural and Food Chemistry, vol. 46, no. 10, pp. 4113-4117, 1998.
 T. Yamaguchi, M. Katsuda, Y. Oda et al., "Influence of polyphenol and ascorbate oxidases during cooking process on the radicalscavenging activity of vegetables," Food Science and Technology Research, vol. 9, no. 1, pp. 79-83, 2003.
 P. Baardseth, F. Bjerke, B. K. Martinsen, and G. Skrede, "Vitamin C, total phenolics and antioxidative activity in tip-cut green beans (Phaseolus vulgaris) and swede rods (Brassica napus var. napobrassica) processed by methods used in catering," Journal of the Science of Food and Agriculture, vol. 90, no. 7, pp. 1245-1255, 2010.
 U. Schwarzmaier, "Cyanogenesis of Dendrocalamus: taxiphyllin," Phytochemistry, vol. 16, no. 10, pp. 1599-1600,1977.
 F. Nartey, "Toxicological aspects of cyanogens in tropical foods," in Toxicology in the Tropics, R. L. Smith and E. R. Bababummi, Eds., pp. 53-73, Taylor & Francis, London, UK, 1980.
 I. Hunter and Y. Fenge, "Cyanide in bamboo shoots," 2000, http://www.inbar.int/publication/txt/INBAR Working Paper No.39.htm.
 J. Vetter, "Plant cyanogenic glycosides," Toxicon, vol. 38, no. 1, pp. 11-36, 2000.
 D. S. Seigler, "Cyanide and cyanogenic glycoside," in Herbivores: Their Interactions with Secondary Plant Metabolites, G. A. Rosentahel and M. R. Berenbaum, Eds., vol. I of The Chemical Participants, pp. 35-77, Academic Press, San Diego, Calif, USA, 1991.
 EFSA, "Opinion of the scientific panel on food additives flavorings, processing aids and materials in contact with food (AFC) on hydrocyanic acids in flavorings and other food ingredients with flavoring properties," European Food Safety Authority Journal, vol. 105, pp. 1-28, 2004.
 Anonymous, "Cyanogenic glycosides in cassava and bamboo shoots, a human health risk assessment," Tech. Rep. 28, Food Standards Australia, Wellington, New Zealand, 2004.
 D. Jones, "Why are so many food plants cyanogenic?" Phytochemistry, vol. 47, no. 2, pp. 155-162,1998.
 M. R. Haque and J. H. Bradbury, "Total cyanide determination of plants and foods using the picrate and acid hydrolysis methods," Food Chemistry, vol. 77, no. 1, pp. 107-114, 2002.
 FSANZ, "Cyanogenic glycosides in cassava and bamboo shoots: a human health risk assessment," Tech. Rep. 28, 2004.
 G. N. P. Pramod Kumar, H. V. Chandrakant, J. V. Annei, B. Manjunatha, B. M. Balaraj, and K. A. Sudharshan Murthy, "Bamboo shoot--is it edible or poisonous?" Journal of Indian Society of Toxicology, vol. 7, no. 2, pp. 19-21, 2011.
 V. L. P Ferreira, K. Yotsuyanagi, and C. R. L. Carvalho, "Elimination of cyanogenic compounds from bamboo shoots Dendrocalamus giganteus Munro," Tropical Science, vol. 35, no. 4, pp. 342-346, 1995.
 T. M. Devi, S. S. Giri, Y. P Devi, and G. A. S. Devi, "An investigation into elimination of cyanide from under process Soibum," The Bioscan, vol. 5, no. 4, pp. 639-642, 2010.
 B. Rana, P Awasthi, and B. K. Kumbhar, "Optimization of processing conditions for cyanide content reduction in fresh bamboo shoot during NaCl treatment by response surface methodology," Journal of Food Science and Technology, vol. 49, no. 1, pp. 103-109, 2012.
 Y. C. Tripathi, "Food and nutrition potential of bamboo," MFP News, vol. 8, no. 1, pp. 10-15,1998.
 T. Wongsakpairod, Bamboo shoot drying using superheated steam [MEng. Thesis], King Mongkut's University of Technology, Bangkok, Thailand, 2000.
 R. Bhardwaj, R. K. Singh, L. Wangchu, and A. K. Sureja, "Bamboo shoots consumption: traditional wisdom and cultural invasion," in Proceedings of the National Conference on Arunachal Pradesh: Tradition in Transition, Link Ecology, Economics and Ethics, NERIST, Nirjuli, India, 2005.
 D. Choudhury, S. K. Jatindra, and G. D. Sharma, "Bamboo shoot: microbiology, biochemistry and technology of fermentation--a review," Indian Journal of Traditional Knowledge, vol. 11, no. 2, pp. 242-249, 2012.
 B. Phithakpol, W. Varanyanond, S. Reunganeepaitoon, and H. Wood, The Traditional Fermented Foods of Thailand, Level 3, ASEAN Food Handling Bureau, Kuala Lumpur, Malaysia, 1995.
 P Shrestha, R. Gautaml, R. B. Rana, and B. Sthapit, "Home gardens in Nepal: status and scope for research and development," in Proceedings of the 2nd International Home Gardens Workshop, J. W. Watson and P B. Eyzaguirre, Eds., pp. 105-124, Witzenhausen, Germany, July 2001.
 S. Satya, L. M. Bal, P Singhal, and S. N. Naik, "Bamboo shoot processing: food quality and safety aspect (a review)," Trends in Food Science and Technology, vol. 21, no. 4, pp. 181-189, 2010.
 S. Diver, Bamboo: A Multipurpose Agroforestry Crop, Appropriate Technology Transfer for Rural Areas, Butte, Montana, 2001, http://www.neat.org/.
 S. Satya, P Singhal, V G. Prabhu, L. M. Bal, and P Suhakar, "Exploring the nutraceutical potential and food safety aspect of bamboo shoot of some Indian species," in Proceedings of the 8th World Bamboo Conference, vol. 6, pp. 78-88, Bangkok, Thailand, September 2009.
 T. Panda and R. N. Padhy, "Sustainable food habits of the hill-dwelling Kandha tribe in Kalahandi district of Orissa," Indian Journal of Traditional Knowledge, vol. 6, no. 1, pp. 103-105,2007
 L. M. Bal, S. N. Naik, and S. Satya, "Scientific validation of indigenous knowledge system for bamboo shoot processing and utilization," in Abstract proceedings of National Seminar on Bamboo Plantation Management and Its Utilization, p. 70, Jodhpur, India, March 2009.
 NMBA, "Bamboo shoot composition," National Mission on Bamboo Application, India, 2009.
 A. Sarmah, S. Thomas, M. Goswami, K. Haridashan, and S. K. Borthakur, "Rattan and bamboo flora of North-East India in a conservation perspective," in Sustainable Management of Forests, A. Arunachalan and M. L. Khan, Eds., pp. 37-45, International Book Distributors, Dehradun, India, 2000.
 L. B. Singha, M. L. Khan, and R. Devi, "Understanding bamboo sector for income generation, employment opportunity and sustainable development of the North East India," Indian Forest, vol. 134, no. 9, pp. 1147-1156, 2008.
 T. P Sharma and S. K. Borthakur, "Ethnobotanical observations on bamboos among Adi tribes in Arunachal Pradesh," Indian Journal of Traditional Knowledge, vol. 7, no. 4, pp. 594-597,2008.
 B. P Bhatt, L. B. Singha, K. Singh, and M. S. Sachan, "Some commercial edible bamboo species of North East India: production, indigenous uses, cost-benefit and management strategies," The Journal of the American Bamboo Society, vol. 17, no. 1, pp. 4-20, 2003.
 K. Jeyaram, T. A. Anand Singh, W. Romi et al., "Traditional fermented foods of Manipur," Indian Journal of Traditional Knowledge, vol. 8, no. 1, pp. 115-121, 2009.
 B. Tamang and J. P Tamang, "Traditional knowledge of biopreservation of perishable vegetable and bamboo shoots in Northeast India as food resources," Indian Journal of Traditional Knowledge, vol. 8, no. 1, pp. 89-95, 2009.
 A. Singh, R. K. Singh, and A. K. Sureja, "Cultural significance and diversities of ethnic foods of Northeast India," Indian Journal of Traditional Knowledge, vol. 6, no. 1, pp. 79-94, 2007
 E. D. Borah, K. C. Pathak, B. Deka, D. Neog, and K. Borah, "Utilization aspects of Bamboo and its market value," The Indian Forester, pp. 423-427, 2006.
 Anonymous, National Mission on Bamboo Technology and Trade Development, Planning Commission, GOI, New Delhi, India, 2003.
 Q. Yang, Z. Duan, Z. Wang, K. He, Q. Sun, and Z. Peng, "Bamboo resources, utilization and ex-situ conservation in Xishuangbanna, South-eastern China," Journal of Forestry Research, vol. 19, no. 1, pp. 79-83, 2008.
 M. Lobovikov, "Bamboo and rattan products and trade," Journal of Bamboo and Rattan, vol. 2, no. 4, pp. 397-406, 2003.
 K. Doley, Report on Study of Feasibility of Establishing a Bamboo Industry in the Atherton Tablelands, Department of Irrigation, Local Government and Ethnic Affairs, Queensland, Australia, 1992.
 P S. Pathak, "Bamboo resources in the world," in Proceedings of the Seminar on Silviculture and Management of Bamboo, pp. 78-87, Jabalpur, India, 1989.
 D. N. Tewari, A Monograph on Bamboo, International Book Distributors, Dehradun, India, 1992.
 K. A. Singh, "Prospect of edible bamboo shoot farming in North-East India," ICAR News, pp. 5-8, 2002.
 B. D. Sharma, D. K. Hore, G. Pandey, and B. M. Wadhwa, "Genetic resource of bamboos in the North-Eastern region of India," Indian Journal of Forestry, vol. 15, no. 1, pp. 44-51,1992.
 C. Renuka, "Rattan of Northeastern India--a cause for great concern," Arunachal Forest News, vol. 14, pp. 8-11,1996.
 S. Godbole, A. Sood, R. Thakur, M. Sharma, and P. S. Ahuja, "Somatic embryogenesis and its conversion into plantlets in a multipurpose bamboo, Dendrocalamus hamiltonii Nees et Arn. Ex Munro," Current Science, vol. 87, no. 7, pp. 885-889, 2002.
 K. N. Subramanlam, "Bamboos--demand and supply of planting stock," INBAR Newsletter, vol. 5, pp. 24-25,1994.
 J. Gielis, "Bamboo and biotechnology," Journal of European Bamboo Society, vol. 6, pp. 27-39,1995.
 M. P. Alexander and T. C. Rao, "In vitro culture of bamboo embryo," Current Science, vol. 37, p. 415,1968.
 S. Saxena and V. Dhawan, "Regeneration and large-scale propagation of bamboo (Dendrocalamus strictus Nees) through somatic embryogenesis," Plant Cell Reports, vol. 18, no. 5, pp. 438-443, 1999.
 A. Sood, P. S. Ahuja, M. Sharma, O. P. Sharma, and S. Godbole, "In vitro protocols and field performance of elites of an important bamboo Dendrocalamus hamiltonii Nees et Arn. Ex Munro," Plant Cell, Tissue and Organ Culture, vol. 71, no. 1, pp. 55-63, 2002.
 F. M. Murlidharan, "Micropropagation of bamboo and rattan," in KFRI Handbook, vol. 15, pp. 1-20, 2002.
 Y. Mishra, P. K. Patel, S. Yadav, F. Shirin, and S. A. Ansari, "A micropropagation system for cloning of Bambusa tulda Roxb," Scientia Horticulturae, vol. 115, no. 3, pp. 315-318, 2008.
 D. Negi and S. Saxena, "Micropropagation of Bambusa balcooa Roxb. through axillary shoot proliferation," In Vitro Cellular & Developmental Biology--Plant, vol. 47, no. 5, pp. 604-610, 2011.
 S. R. Singh, S. Dalal, R. Singh, A. K. Dhawan, and R. K. Kalia, "Ascertaining clonal fidelity of micropropagated plants of Dendrocalamus hamiltonii Nees et Arn. Ex Munro using molecular markers," In Vitro Cellular & Developmental Biology--Plant, vol. 49, no. 5, pp. 572-583, 2013.
 R. Yasodha, S. Kamala, S. P. A. Kumar, K. Kalaiarasi, and P. D. Kumar, "Effect of glucose on in vitro rooting of mature plants of Bambusa nutans," Scientia Horticulturae, vol. 116, no. 1, pp. 113-116, 2008.
 S. Saxena and V. Dhawan, "Micropropagation research in South Asia," in Constrains to Production of Bamboos and Rattan, Report of a Consultation Held in Bangalore, India, INBR Technical Report No. 5, pp. 101-114, International Networkfor Bamboo and Rattan, New Delhi, India.
 S. M. S. D. Ramanayake and K. Yakandawala, "Micropropagation of the giant bamboo (Dendrocalamus giganteus Munro) from nodal explants of field grown culms," Plant Science, vol. 129, no. 2, pp. 213-223,1997.
 S. R. Singh, S. Dalal, R. Singh, A. K. Dhawan, and R. K. Kalia, "Micropropagation of Dendrocalamus asper (Schult. &Schult. F. Backer ex K. Heyne): an exotic edible bamboo," Journal of Plant Biochemistry and Biotechnology, vol. 21, no. 2, pp. 220-228,2012.
 P. Sharma and K. P. Sarma, "In vitro propagation of Bambusa balcooa for better environment," in Proceedings of the International Conferences on Advances in Biotechnology and Pharmaceutical Sciences (ICABPS 11), Bangkok, Thailand, December 2011.
 T. Murashige and F. Skoog, "A revised medium for rapid growth and bio assay with tobacco tissue culture," Physiologia Plantarum, vol. 15, no. 3, pp. 473-479,1962.
 R. K. Agnihotri and S. K. Nandi, "In vitro shoot cut: a high frequency multiplication and rooting method in the bamboo Dendrocalamus hamiltonii," Biotechnology, vol. 8, no. 2, pp. 259263, 2009.
 F. Shirin and P. K. Rana, "In vitro plantlet regeneration from nodal explants of field grown culms in Bambusa glaucescens Willd," Plant Biotechnology Reports, vol. 1, pp. 141-147, 2007.
 S. Ogita, H. Kashiwagi, and Y. Kato, "In vitro node culture of seedlings in bamboo plant, Phyllostachys meyeri McClure," Plant Biotechnology, vol. 25, no. 4, pp. 381-385, 2008.
 A. F. Mascarenhas, A. L. Nadgir, and S. R. Thengane, "Potential application of tissue culture for propagation of Dendrocalamus strictus," in Proceedings of the International Bamboo Workshop, I. V. R. Rao, R. Gnanaharan, and R. Sastry, Eds., Bamboo, Current Research, Kerala Forest Research Institute/ IDRC, Cochin, India, November 1988.
 S. R. Singh, S. Dalal, R. Singh, A. K. Dhawan, and R. K. Kalia, "Seasonal influences on in vitro bud break in Dendrocalamus hamiltonii Arn. Ex Munro nodal explants and effect of culture microenvironment on large scale shoot multiplication and plantlet regeneration," Indian Journal of Plant Physiology, vol. 17, no. 1, pp. 9-21, 2012.
 P. Nongdam, "Bamboos as source of nutrient rich ethnic foods of North-East India and their conservation via micropropagation," in Proceedings of the 3rd Annual International Conference on Advances in Biotechnology (BIOTECH 13), pp. 713, Singapore, March 2013.
 K. D. Mudoi and M. Borthakur, "In vitro micropropagation of Bambusa balcooa Roxb. through nodal explants from fieldgrown culms and scope for upscaling," Current Science, vol. 96, no. 7, pp. 962-966, 2009.
 P. Kapoor and I. U. Rao, "In vitro rhizome induction and plantlet formation from multiple shoots in Bambusa bambos var. gigantea Bennet and Gaur by using growth regulators and sucrose," Plant Cell, Tissue and Organ Culture, vol. 85, no. 2, pp. 211-217, 2006.
 G. Nemeth, Induction of Rooting, Biotechnology in Agriculture and Forestry 1, Trees, Springer, Heidelberg, Germany, 1986.
 J. Gielis and J. Oprins, "Bamboo for Europe," EU-FAIR CT1747 Final Individual Report, 2000.
 S. Saxena, "In vitro propagation of the bamboo (Bambusa tulda Roxb.) through shoot proliferation," Plant Cell Reports, vol. 9, no. 8, pp. 431-434, 1990.
 S. M. Arshad, A. Kumar, and S. K. Bhatnagar, "Micropropagation of Bambusa wamin through proliferation of mature nodal explants," Journal of Biological Research, vol. 3, pp. 59-66, 2005.
 S. M. S. D. Ramanayake, K. M. M. N. Maddegoda, M. C. Vitharana, and G. D. G. Chaturani, "Root induction in three species of bamboo with different rooting abilities," Scientia Horticulturae, vol. 118, no. 3, pp. 270-273, 2008.
 Y. Watanable, Y. Sawa, N. Nagaoka, and T. Kozai, "A new micropropagation system for Pleioblastus pygaeus Nakai," in Proceedings of the International Symposium Royal Project Foundation, pp. 94-101, Chin Mai, Thailand, August 2000.
 W. S. Devi and G. J. Sharma, "In vitro propagation of Arundinaria callosa Munro-an Edible bamboo from nodal explants of mature plants," The Open Plant Science Journal,vol. 3, pp. 35-39, 2009.
 N. S. Bag, S. Chandra, L. M. S. Palni, and S. K. Nandi, "Micropropagation ofDev-ringal [Thamnocalamus spathiflorus (Trin.) Munro]--a temperate bamboo, and comparison between in vitro propagated plants and seedlings," Plant Science, vol. 156, no. 2, pp. 125-135, 2000.
 J. Gielis, H. Peeters, K. Gillis, J. Oprins, and P. C. Debergh, "Tissue culture strategies for genetic improvement of bamboo," Acta Horticulturae, vol. 552, pp. 195-200, 2001.
 J. M. S. Tomar, D. K. Hore, and A. Annadurai, "Bamboos and their conservation in North-East India," Indian Forester, vol. 13, pp. 817-824, 2009.
P. Nongdam and Leimapokpam Tikendra
Department of Biotechnology, Manipur University, Canchipur, Imphal, Manipur 795003, India
Correspondence should be addressed to P. Nongdam; email@example.com
Received 20 March 2014; Revised 19 May 2014; Accepted 26 May 2014; Published 20 July 2014
Academic Editor: Othmane Merah
Table 1: Comparison of nutrient composition of young bamboo shoots of Bambusa tulda and Dendrocalamus hamiltonii with some common vegetables . Nutrients Bambusa Dendrocalamus Daucus tulda hamiltonii carota Amino acids (g/100 g) 3.65 3.18 0.20 Protein (g/100 g) 3.69 3.72 0.90 Carbohydrate (g/100 g) 6.92 5.50 10.60 Fats (g/100 g) 0.48 0.41 0.10 Fibers (g/100 g) 3.97 3.90 1.20 Vitamin C (mg/100 g) 1.42 2.45 15.00 Vitamin E (mg/100 g) 0.61 0.71 3.00 Potassium (mg/100 g) 408 416 108.00 Iron (mg/100 g) 3.19 2.69 1.03 Calcium (mg/100 g) 4.06 3.00 80.00 Cupper (mg/100 g) 0.44 0.29 0.10 Sodium (mg/100 g) 19.96 9.32 35.60 Zinc (mg/100 g) 0.72 0.70 0.36 Nutrients Raphanus Spinacea Solanum sativus oleracea tuberosum Amino acids (g/100 g) 0.40 0.30 0.20 Protein (g/100 g) 0.70 2.00 1.60 Carbohydrate (g/100 g) 3.40 2.90 22.6 Fats (g/100 g) 0.40 0.70 0.10 Fibers (g/100 g) 0.60 2.00 0.40 Vitamin C (mg/100 g) 1.60 0.60 0.40 Vitamin E (mg/100 g) 15.00 28.10 19.70 Potassium (mg/100 g) 393.00 558.00 424.00 Iron (mg/100 g) 1.00 2.70 0.80 Calcium (mg/100 g) 35.00 9.90 12.00 Cupper (mg/100 g) 0.02 0.10 0.16 Sodium (mg/100 g) 39.00 79.00 11.00 Zinc (mg/100 g) 0.30 0.50 0.30 Nutrients Abelmoschus Curcuma Cucurbita esculentus sativus maxima Amino acids (g/100 g) 0.30 0.10 0.20 Protein (g/100 g) 1.90 0.60 1.40 Carbohydrate (g/100 g) 6.40 2.50 6.50 Fats (g/100 g) 0.20 0.10 0.40 Fibers (g/100 g) 1.20 0.40 1.10 Vitamin C (mg/100 g) 1.20 0.70 0.07 Vitamin E (mg/100 g) 13.00 3.20 0.90 Potassium (mg/100 g) 103.00 135.00 340.00 Iron (mg/100 g) 0.35 0.90 0.80 Calcium (mg/100 g) 56.00 14.00 21.00 Cupper (mg/100 g) 0.11 0.09 0.10 Sodium (mg/100 g) 6.90 2.00 5.60 Zinc (mg/100 g) 0.42 0.23 0.30 Table 2: Nutrient content of freshly harvested shoots of some bamboo species [7-9]. Nutrients B. bamboos B. nutans B. polymorpha Amino acids (g/100 g) 3.98 3.89 3.42 Protein (g/100 g) 3.57 2.84 3.64 Carbohydrate (g/100 g) 5.42 5.47 5.44 Fats (g/100 g) 0.50 0.40 0.46 Fibres (g/100 g) 4.49 2.28 3.81 Vitamin C (mg/100 g) 1.90 1.19 2.60 Vitamin E (mg/100 g) 0.61 0.47 0.49 Calcium (mg/100 g) 0.36 1500 180.69 Phosphorus (mg/100 g) 30.12 900 15.06 Iron (mg/100 g) 3.00 -- 1.53 Sodium (mg/100 g) 10.10 -- -- Potassium (mg/100 gm) -- 30.0 -- Magnesium (mg/100 gm) 5.38 40.0 -- Nutrients B. tulda B. vulgaris D. asper Amino acids (g/100 g) 3.65 3.57 3.12 Protein (g/100 g) 3.69 3.64 3.59 Carbohydrate (g/100 g) 6.92 6.51 4.90 Fats (g/100 g) 0.48 0.50 0.40 Fibres (g/100 g) 3.97 4.24 3.54 Vitamin C (mg/100 g) 1.42 4.80 3.20 Vitamin E (mg/100 g) 0.61 0.52 0.91 Calcium (mg/100 g) 1300 320 5.51 Phosphorus (mg/100 g) 700 220 40.95 Iron (mg/100 g) 1.57 -- 3.37 Sodium (mg/100 g) 12.96 400 10.14 Potassium (mg/100 gm) 20.0 920 464 Magnesium (mg/100 gm) 40.0 100 10.14 Nutrients D. giganteus D. strictus Amino acids (g/100 g) 3.96 3.07 Protein (g/100 g) 3.11 2.60 Carbohydrate (g/100 g) 5.10 6.17 Fats (g/100 g) 0.39 0.33 Fibres (g/100 g) 2.60 2.26 Vitamin C (mg/100 g) 3.28 2.43 Vitamin E (mg/100 g) 0.69 0.58 Calcium (mg/100 g) 26.93 139.5 Phosphorus (mg/100 g) 12.57 58.13 Iron (mg/100 g) 1.06 2.91 Sodium (mg/100 g) 3.64 0.08 Potassium (mg/100 gm) 275 -- Magnesium (mg/100 gm) 9.57 0.17 Note: Hyphen (-) in table indicates authentic data not available for the particular bamboo species. Table 3: Nutrient composition of raw, boiled, and fermented shoots of different bamboo species [6, 8,10,11]. Nature of Bamboo Carbohydrate Protein shoots species (g/100 g) (g/100 g) Dendrocalamus strictus 85.98 21.51 Raw Dendrocalamusasper 2.90 25.80 shoots D. giganteus 5.10 -- Bambusa vulgaris 3.40 25.70 Bambusa nutans 3.30 21.10 Dendrocalamus strictus 5.00 -- Boiled Dendrocalamus asper 3.10 17.10 shoots D. giganteus -- 11.66 Bambusa vulgaris 5.00 13.50 Bambusa nutans 5.10 17.30 Dendrocalamus strictus -- -- Fermented Dendrocalamus asper -- -- shoots D. giganteus -- -- Bambusa vulagaris -- -- Bambusa nutans -- -- Nature of Bamboo Fats Vitamin C shoots species (g/100 g) (mg/100 g) Dendrocalamus strictus 0.10 5.80 Raw Dendrocalamusasper 3.59 3.30 shoots D. giganteus 0.39 3.28 Bambusa vulgaris 0.20 13.70 Bambusa nutans 1.00 5.30 Dendrocalamus strictus -- -- Boiled Dendrocalamus asper -- -- shoots D. giganteus -- -- Bambusa vulgaris -- -- Bambusa nutans -- -- Dendrocalamus strictus -- -- Fermented Dendrocalamus asper -- -- shoots D. giganteus -- 0.32 Bambusa vulagaris -- -- Bambusa nutans -- -- Nature of Bamboo Vitamin E Fibres shoots species (mg/100 g) (g/100 g) Dendrocalamus strictus -- 0.98 Raw Dendrocalamusasper 0.91 0.70 shoots D. giganteus 0.69 -- Bambusa vulgaris -- 0.70 Bambusa nutans -- 0.76 Dendrocalamus strictus -- 0.96 Boiled Dendrocalamus asper -- 0.70 shoots D. giganteus -- -- Bambusa vulgaris -- 0.96 Bambusa nutans -- 0.75 Dendrocalamus strictus -- -- Fermented Dendrocalamus asper -- -- shoots D. giganteus 1.09 0.21 Bambusa vulagaris -- -- Bambusa nutans -- -- Note: Hyphen (-) in table indicates authentic data not available for the particular bamboo species.
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|Author:||Nongdam, P.; Tikendra, Leimapokpam|
|Publication:||International Scholarly Research Notices|
|Date:||Jan 1, 2014|
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