Ethno-botanical studies by different researchers on Dioscorea species in Orissa, India


 Sanjeet kumar

Ethnobotanical Leaflets 10: 149-173. 2006.

Ethnomedicinal Plants used by the Tribals of Similipal Bioreserve, Orissa, India: A Pilot Study

Kambaska Kumar Behera

Dioscorea bulbifera L.
Family with Collection Number - (DIOSCCOREACEAE). /287
Vernacular Name: Jo-sang (Lo); Beng-Sang (Sa, Mu), Khamba-alu (O, Ba,).
Parts Used: Tuber
Ethnomedicinal Uses: Tuber paste (2gm) with paste of keon-kanda (Costus specious) (1gm) is prescribed as a cure for piles. Gandidhara (Mu); Kundabai (Lo); Dukura.

Int. J. of Pharm. & Life Sci. (IJPLS), Vol. 2, Issue 11: Nov.: 2011, 1206-1210
Medicinal plants in an Urban environment; herbaceous medicinal flora from the campus of Regional Institute of Education, Bhubaneswar, Odisha
Sanjeet Kumar and M. K. Satapathy
Dioscorea alata (L.) Dioscoreaceae Cultivated,
Climber, Tubers are edible
 Dioscorea puber Bl. Enum. Dioscoreaceae Wild,
Climber, Bulbils and tubers are edible



Ethno Med, 4(1): 53-61 (2010)
Potential Medicinal Plants Used by the Tribal of Deogarh District, Orissa, India
S. C. Sahu, N. K. Dhal and R.C. Mohanty

Dioscorea bulbifera L. Dioscoreaceae Kalamati,10162 Khamba-alu Tuber Tuber paste 2g mixed with 4g young leaf paste of (Costus specious) is administered for fifteen days against rheumatism.


Ethnobotanical Leaflets 14: 889-910, 2010.
Use of Ethnomedicinal Plants by Natives of Bargarh District of Orissa, India
Alok Ranjan Sahu, Niranjan Behera  and S. P. Mishra
Dioscorea bulbifera: Tuber is used against Piles  


IJTK, 2004, 3(1):72-79
Ethno-medico- botanical survey of Kalahandi district of Orissa
S.Nayak, S.K.Behera and M.K.Mishra

Dioscorea bulbifera : Root powder is applied externally in case of hernia and hydrocele. Tuber powder is used against scorpion bite.

Ethnobotanical Leaflets 11: 122-140. 2007.
Ethnobotanical Exploration of Malkangiri District of Orissa ,India
A.B. Prusti and K.K.Behera
Dioscorea bulbifera L. : After prolonged boiling the tubers are eaten.


J. Hum. Ecol., 14(3): 165-227 (2003)
Ethno-medicinal Informations from Orissa State, India, A Review
Sarita Das, S.K. Dash and S.N. Padhy

Dioscorea bulbifera L. : Leaf Juice applied on Skin infections. Leaf Ground and rubbed all over acute itching


IJTK, 2010, 9(1):68-72
SD Rout and SK Panda
Ethnomedicinal plant resource of Mayurbhanj district, Orissa
D.wallichii: Root is used against stomach pain


Sustainable food habits of the hill-dwelling Kandha tribe in Kalahandi
district of Orissa
Tribhubana Panda*1 & Rabindra N Padhy2
1Kalahandi Institute for Tribology and Ethnobiology, Jilingdar, Dedar 766014, Kalahandi, Orissa
 2Department of Botany, Government Autonomous College, Bhawanipatna 766001, Kalahandi, Orissa
Received 6 September 2005; revised 30 January 2006
An ethnobotanical survey of food practices of an aboriginal, hill-dwelling Kandha tribe of Kalahandi district, revealed that in addition to their conventional foods, rice, finger millet and a few popular pulses, they use many types of naturally occurring unusual additional food items such as carnals of mango, several types of tubers of the genus Dioscorea, wild bean Mucuna utilis Wall. ex Wight, Madhuca indica J.F.Gmel. flowers, Caryota urens pith, Tamarindus indica seeds, younglings of bamboo (Dendrocalamus strictus) and wild mushrooms. Detailed methods of processing of these items are unique and bitter tasting chemicals (alkaloids) of these food items are removed by repeated boiling and discarding the boiled water.

Recent Research in Dioscorea species (Bān Aālu) in Odisha, India



Sanjeet kumar


Nature and Science, 2009;7(3), ISSN 1545-0740, http://www.sciencepub.net, naturesciencej@gmail.com
Relative Agronomic performance of different Dioscorea species found in different parts of Orissa.
Kambaska Kumar Behera , Santilata Sahoo  and Aratibala Prusti

ABSTRACT: A study was under taken to quantify the relative agronomic performance of twelve Dioscorea species (11 wild and one cultivated species D.esculenta) found in different parts of Orissa .Various agro morphological character starting from plant height to yield per plant was evaluated among the twelve different Dioscorea species and presented in tabular form as per the standard agro metric method.The agronomic character analysis revealed that plant height was significantly superior in D. hispida (3.21 m) followed by the shortest height was noticed in D. oppositifolia (1.98 m). However at final stage of the crop highest number of leaves are found in D. oppositifolia (179) and D. wallichii (156). Tuber number per plant was the highest in D. esculenta (6.2) and there was only one tuber in D. bulbifera. The tuber: shoot ratio was significantly the highest in D. wallichii (2.43) and the lowest in D. oppositifolie (0.833). The ratio was very low in D. bulbifera and D. hamiltonii .The yield (kg/plant) was significantly highest in D. bulbifera (1.646 kg) and lowest yield was obtained with D. belophylla (0.654 kg) followed by D. Pubera (0.678 kg). From the study it is concluded that each species has their own identical agronomic character with certain similarities and dissimilarities among themselves. [Nature and Science. 2009;7(3):23-35]. (ISSN: 1545-0740).

Nature and Science, 2009;7(7), ISSN 1545-0740, http://www.sciencepub.net, naturesciencej@gmail.com
Biochemical Quantification of protein , Fat, Starch, Crude fibre, Ash and Dry matter content in
different Collection of Greater Yam (Dioscorea alata L.) found in Orissa
Kambaska Kumar Behera, Trinanth Maharana , Santilata Sahoo and Aratibala Prusti
Abstract
A study was under taken to quantify the biochemical composition of protein, fat, starch, crude fiber, ash and dry matter in 22 different collections (C1 to C22) of Dioscorea alata fresh tubers. In the present study C-18 was found with highest dry matter (33.33%) where as lowest in C-3 (24.91%). The Average dry matter was highest in intermediate shape groups and collections with white flesh tubers. Starch percentage is highest in C-20 (82.51%) followed by C-1, C-7, C-3, C-22 and lowest is estimated in C-15 (78.36%). The highest protein content in dry matter of tuber was observed with C-1 (9.67%) and the lowest protein content was observed with C-13 (7.31%). The lowest fat content, however, was observed in C-11 (0.67%) and highest value was with C-2 (1.24%). C-1 had the lowest ash content of 1.89 % whereas C-15 had the highest value of 7.08 %. However, the ash content was towards the higher side in the intermediate group (5.85%). The crude fiber range was higher in the intermediate group i.e. out of five collections four were having more than 2% crude fiber. From the present investigation it is concluded that different collections of D. alata vary greatly for their dry matter, starch, protein, fat, ash and crude fiber content depending on different collection groups and the geographical regions.
  
Journal of Root Crops, 2010, Vol. 36 No. 1, pp. 27-32 Micropropagation of greater yam through vine nodes 27
Indian Society for Root Crops
ISSN 0378-2409

Micropropagation of Greater Yam (Dioscorea alata L.
cv. Hatikhujia) Through Vine Nodes
Kambaska Kumar Behera, Santilata Sahoo and Aratibala Prusti
Abstract
Nodal segments of vines from the field grown plants of Dioscorea alata L. (cv. Hatikhujia) were cultured on Murashige and Skoog’s basal medium supplemented with different concentrations and combinations of BAP and Kinetin (Kn) along with NAA. Explants cultured in MS basal medium supplemented with 2.0 mg-l Kn +1.0 mg-l BAP + 0.5 mg-l NAA showed the best response to shoot multiplication. When in vitro shoots were inoculated on to the half-strength MS basal media supplemented with 2.0 mg-l NAA, rooting was more profuse. Rooted shoots were transplanted in the green house for hardening and their survival was 90% under field conditions with average yield of 0.612 Kg of tuber per plant.

Not. Bot. Hort. Agrobot. Cluj 37 (1) 2009, 94-102
Print ISSN 0255-965X; Electronic ISSN 1842-4309
Notulae Botanicae Horti AgrobotaniciCluj-Napoca

Regeneration of Plantlet of Water Yam (Dioscorea oppositifoliaaL.) through In Vitro Culture from Nodal Segments
Kambaska Kumar BEHERA1) , Santilata SAHOO 1) , Aratibala PRUSTI 2)
1)P. G. Deptt. of Botanty Utkal University, Vanivihar, Bhubaneswar, Orissa, India; kambaska@yahoo.co.in
2) P.N. College (Autonomous) Khurda, Orissa, India

Abstract
The present investigation was carried out with a view to regenerate plantlet of Dioscorea oppositifolia L through in vitro culture. Nodal vine segments from 45days old plants of field grown Dioscorea opositifolia were used as explants for initial culture. The explants were cultured on MS (Murashige and Skoog’s, 1962) medium supplemented with different concentration and combination of cytokinines and auxines for primary shoot proliferation. The best shoot proliferation was observed in MS medium containing 2.0 mg-l KINETIN +1.0 mg-l BAP+0.5mg-l NAA + 100mg-l ascorbic acid where 90 % of explants showed proliferation with highest rate of shoot multiplication (10.5 shoots per explant). For rooting, the in vitro micro shootlets were inoculated on to the half-strength MS basal media supplemented with 2.0 mg/l NAA and rooting was more profuse with micro tubers in the base of the root primordia. Rooted shoots were transplanted in the green house for hardening and their survival rate was 90 % in the field condition. 
Nature and Science 2009; 7(12)
http://www.sciencepub.net/nature 4 8 naturesciencej@gmail.com

Response of Vine Cuttings to Rooting in Different Months in Three
Dioscorea species
Kambaska Kumar Behera, Santilata Sahoo,  Trinanth Maharana,  and Debashrita Pani

Abstract: Availability period of vine cuttings of different Dioscoreas in the field reveals that Dioscorea alata L. can be maintained throughout the year for collection of vine cuttings. On the other hand vine cuttings of D. oppositifolia L., can be collected from June to December and D. hispida Dennst., can provide cuttings from June to October. Earlier or latter to this no cuttings will be available. Each vine cutting should have one or two nodes. One of the nodes should be in soil. One leaf must be there in each cutting. Since the leaf is responsible for photosynthesis and transpiration the area of the leaf may be kept in a comfortable size by trimming to maintain a balance between
transpiration, photosynthesis and respiration.

International Journal of Biological Technology (2012) 3(1): 11-19.
ISSN: 0976 – 4313

Study of wild edible plants among tribal groups of Simlipal Biosphere Reserve
Forest, Odisha, India; with special reference to Dioscorea species
Sanjeet Kumar, Padan Kumar Jena, Prakash Kumar Tripathy

Abstract

The present study documented first time some of the most preferred wild food sources among the tribes Mankirdia, Kharia, Kolha, Santhal and others inhabiting in Simlipal Biosphere Reserve Forest, Odisha, India, particularly highlighting the importance of Dioscorea species. A total of 79 wild edible plants including 11 species of Dioscorea were assessed with respect to their availability, consumption pattern and harvesting. These foods are also stored by the tribal groups using different process for critical periods of food shortage and famine. The study emphasizes upon the need for exploring food resource available for wild plants and conservation of wide biodiversity of Odisha.


ANNONACEAE: Largest Family of Magnoliales(order)

Sanjeet kumar
sanjeet.biotech@gmail.com

Annonaceae,  the custard-apple, or annona, family, the largest family of the magnolia order of family of flowering plants consisting of trees, shrubs or rarely lianas. Seven genera, Annona, Anonidium, Rollinia, Uvaria, Melodorum, Asimina and Stelechocarpus produce edible fruits. The family is concentrated in the tropics, with few species found in temperate regions. About 900 species are Neotropical, 450 are Afrotropical, and the other species Indomalayan. They are trees, shrubs, or climbers, wood and leaves often aromatic; indument of simple or less often (Uvaria, Annona) stellate hairs. Leaves alternate, normally distichous. Stipules absent. Petiole usually short; leaf blade simple, venation pinnate, margin entire. Inflorescences terminal, axillary, leaf-opposed, or extra-axillary [rarely on often underground suckerlike shoots]. Flowers usually bisexual, less often unisexual, solitary, in fascicles, glomerules, panicles, or cymes, sometimes on older wood, usually bracteate and/or bracteolate. Sepals hypogynous, [2 or]3, imbricate or valvate, persistent or deciduous, rarely enlarging and enclosing fruit, free or basally connate. Petals hypogynous, 3–6(–12), most often in 2 whorls of 3 or in 1 whorl of 3 or 4[or 6], imbricate or valvate, sometimes outer whorl valvate and inner slightly imbricate. Stamens hypogynous, usually many, rarely few, spirally imbricate, in several series; filaments very short and thick; anther locules 2, contiguous or separate, rarely transversely locular, adnate to connective, extrorse or lateral, very rarely introrse, opening by a longitudinal slit; connectives often apically enlarged, usually ± truncate, often overtopping anther locules, rarely elongated or not produced. Carpels few to many, rarely solitary, free or less often connate into a 1- locular ovary with parietal placentas; ovules 1 or 2 inserted at base of carpel or 1 to several in 1 or 2 ranks along ventral suture, anatropous; styles short, thick, free or rarely connate; stigmas capitate to oblong, sometimes sulcate or 2-lobed. Fruit usually apocarpous with 1 to many free monocarps, these sometimes moniliform (constricted between seeds when more than 1-seeded), often fleshy, indehiscent, rarely dehiscent (Anaxagorea, Xylopia), and often with base extended into stipe, rarely on slender carpophores (Disepalum), less often syncarpous with carpels completely connate and seeds irregularly arranged and sometimes embedded in fleshy pulp. Seeds 1 to many per monocarp or many per syncarp, often arillate; endosperm copious, ruminate; embryo minute, near hilum. About 129 genera and over 2,300 species: tropics and subtropics, especially in Old World; 24 genera (one endemic, three introduced) and 120 species (41 endemic, 11 introduced) in China.  The flowers often open before the petals have fully expanded making it easy to underestimate floral dimensions.  One of the major studies of the Annonaceae of tropical Asia was by Suzanne Jovet-Ast (1914–2006), who published an account of the Indochinese species under her maiden name, Ast (Fl. Indo-Chine, Suppl. 1: 62–121. 1938). Unfortunately, she failed to provide Latin descriptions for her many new taxa, none of the names of which was therefore validly published. Her new combinations were validly published, however, and she did subsequently validate a few species of Goniothalamus under her maiden name; but she did not validate most of her new species until after she married and took up the name “Jovet-Ast.” These later names form the major part of all her publications, so we have chosen to cite her as “Jovet-Ast [“Ast”]” for those taxa validated under her maiden name.

Tsiang Ying & Li Ping-t’ao. 1979. Annonaceae. In: Tsiang Ying & Li Ping-t’ao, eds., Fl. Reipubl. Popularis Sin. 30(2): 10–175.


1a. Fruit syncarpous, with completely united carpels and seeds embedded in pulp (usually cultivated as fruit trees).
2a. Outer petals usually free, abaxially flat ........................................................................................ Annona
2b. Outer petals connate at base, abaxially spurred or winged ....................................................Rollinia

1b. Fruit apocarpous, with carpels forming free, often stipitate, monocarps.
3a. Sepals or inner petals and sometimes also outer petals clearly imbricate; stellate hairs often present.
4a. Trees or self-supporting shrubs; stellate hairs absent; sepals imbricate; petals valvate or very
       minutely imbricate; ovules 1 per carpel ..............................................................Trivalvaria

4b. Climbing shrubs; stellate hairs present; sepals valvate; inner petals and sometimes also outer
      Petals imbricate; ovules 2 or more per carpel.
5a. Petals spreading at anthesis; torus depressed .......................................Uvaria
5b. Petals incurved at anthesis, not opening widely; torus flattened, margin prominent
                ……. Cyathostemma
3b. Sepals and inner and outer petal whorls all valvate or rarely very narrowly imbricate at tip only (only
1 whorl of petals present in Dasymaschalon); simple hairs usually present, less often plant glabrous.
6a. Climbing shrubs.
7a. Peduncles and fruiting pedicels hooklike ...................................Artabotrys
7b. Peduncles and fruiting pedicels not hooklike.
8a. Monocarps ellipsoid, moniliform when more than 1-seeded; petals basally constricted
      to form enclosed floral chamber around stamens and carpels .....................Desmos
8b. Monocarps globose to cylindric, never moniliform; petals not constricted.
9a. Monocarp stipes 5.3–7.5 cm; outer petals usually much larger than inner petals;
      Stamen connectives apically truncate……………………….Friesodielsia
9b. Monocarp stipes 0.3–4 cm; outer petals only slightly larger than inner petals; stamen
                                                  connectives apically acuminate to obtuse ..........................Fissistigma

6b. Trees or erect shrubs.
10a. Petals (2 or)3, in 1 whorl ..........................................................Dasymaschalon
10b. Petals 6, in 2 whorls.
11a. Inner petals basally clawed or stipitate, laminas vaulted and connate into an apical cap
                                     at least initially.
12a. Outer petals 2–7 mm, usually smaller than inner petals and similar to sepals.
13a. Inner petals with a long basal claw, usually apically lozenge-shaped and
        Cohering by their margins into a cap over stamens and carpels, sometimes
        with their tips conspicuously recurved; pedicel 0.2–1.2 cm ..........Orophea

13b. Inner petals with a short basal claw, shallowly saccate, at first cohering by
        Their margins but soon free; pedicel usually 1.4–10 cm………….. Miliusa

12b. Outer petals more than 12 mm, equaling or longer than inner petals, conspicuously
                                                    different from sepals.
14a. Stamens linear-oblong; inner petals each with a short claw…Goniothalamus
14b. Stamens cuneate; inner petals each with a long claw or stipe.

15a. Outer petals longer than inner petals ..................Mitrephora
15b. Outer petals shorter than inner petals .................Pseuduvaria
11b. Inner petals not basally clawed, spreading or connivent and apically 3-edged.
16a. Stamen connectives apically acuminate.
17a. Petals 5–8 cm, linear to linear-lanceolate ...Cananga
17b. Petals 0.7–1 cm, ovate-triangular to ovate-oblong, usually incurved at base
18a. Monocarps dehiscent, stipe clavate; ovules 2 per carpel
               …………………Anaxagorea
18b. Monocarps indehiscent, stipe not clavate; ovules 5–22 per carpel
                                 ..................Alphonsea
16b. Stamen connectives apically truncate, rounded, or broadly 3-angular.
19a. Ovules 1 or 2(or 3) per carpel, basally or nearly basally inserted.
20a. Inner petals concave and incurved to cover stamens; fruiting
 carpels free but usually connivent …………..Popowia
20b. Inner petals spreading; fruiting carpels free and not connivent

21a. Monocarp bases extended into stipes, not articulate at
         base ................... 14. Polyalthia
21b. Monocarps on slender carpophores, articulate between
        apex of carpophore and base of monocarp ....Disepalum
19b. Ovules many per carpel, ventrally inserted.
22a. Flower buds lanceolate, apically long beaked and 3-
        angled; sepals connate at base or beyond into a cup…
        …….Xylopia
22b. Flower buds ovoid, apically rounded; sepals connate at base but not into a cup; petals flat or cucullate; anther locules not transversely septate.

23a. Petals flat; stamen connectives apically rounded
        stigmas subcapitate, not constricted at base;
        monocarps almost sessile ……..Meiogyne
23b. Petals cucullate; stamen connectives apically truncate to subtruncate; stigmas ovoid, constricted at base; monocarps long stipitate ……Chieniodendron
Monophyly and inter-familial systematics have been well supported for Annonaceae by a combination of morphological and molecular evidence. The APG II system places Annonaceae Combined plastid DNA marker and morphological character analysis of Anaxagorea and other Annonaceae and basal angiosperm genera suggest that Anaxagorea is an ancestral clade, sister to the rest of the family. This may confirm the hypothesis that morphological traits shared with other Magnoliales species (such as 2-ranked phyllotaxis, monosulcate pollen, and laminate stamens) represent ancestral characters, while derived characters observed in other genera have evolved independently multiple times. These analyses also support a biogeographic history in which Annonaceae, and perhaps other basal angiosperm clades, originated in South America during the Cretaceous, radiating due to migration events throughout Africa to Asia and Central to North America.  Guatteria, with its approximately 265 species, is the largest genus of Annonaceae, and might be broken into three small genera based on molecular characters from multiple locations.  Tribe Saccopetaleae is another group of Annonaceae that is awaiting review as recent molecular studies suggest that this tribe is not monophyletic at all
Common Uses
The large, edible, pulpy fruits of some members typically called "anona" by Spanish and Portuguese speaking people of the family's Neotropical range, include species of Annona: custard apple (A. reticulata), cherimoya (A. cherimola), soursop/guanábana/graviola (A. muricata), sweetsop (A. squamosa), ilama (A. diversifolia), soncoya (A. purpurea), atemoya (a cross between A. cherimola and A. squamosa); and biriba (Rollinia deliciosa, which may require reclassification under Annona.). The names of many of those fruits are sometimes used interchangeably. Recently, consumption of the neotropical annonaceous plant Annona muricata (soursop, graviola, guanabana) has been strongly associated as a causal agent in "atypical Parkinsonsism." The causative agent, annonancin, is present in many of the annonaceae. It is thought to be responsible for up to 70% of Parkinsonian conditions in Guadeloupe. Exposure is typically through traditional food and "natural" medicines. Asimina triloba (American pawpaw, prairie banana) has an Eastern U.S. distribution, and is currently under agricultural investigation as a commercial crop. The bark, leaves and roots of some species are used in folk medicines. Lancewood is a tough, elastic and heavy wood obtained from the from species of the family Annonaceae located in West Indies and The Guianas. It was often used especially for carriage shafts. It is brought into commerce in the form of taper poles of about 6 metres in length and from 15 to 20 cm in diameter at the thickest end. The black lancewood or carisiri of The Guianas is of remarkably slender form. The Yellow lancewood tree is found in tolerable abundance throughout The Guianas, and used by the Indians for arrow-points, as well as for spars, beams, etc. Some Bowyers use this wood for making longbows but use the term 'lemonwood' or 'degame' to describe the wood the bow is made from. Some species of the family, such as Cananga odorata (ylang-ylang) also have aromatic oil and are used for perfumes or spices.  Some species are also grown as ornamental plants, especially the Indian species Polyalthia longifolia pendula.
Chemical constituents
Pharmaceutical research has found antifungal, bacteriostatic, antimalarial, and especially cytostatic capability of some chemical constituents of the leaves and bark. A large number of chemical compounds, including flavonoids, alkaloids and acetogenins, have been extracted from the seeds and many other parts of these plants. Flavonoids and alkaloids have shown antibacterial properties, and have been used for treatment of medical conditions, such as skin disease, intestinal worms and inflammation of the eye. Potential pharmaceutical products are currently in early experimental trials in animal models and cell-lines.  Acetogenins are thought to have anti-HIV and anti-cancer effects. A wide variety of products have been developed and are available for cancer treatment.  Flavonoids and alkaloids contained in the leaves and bark of several species of the family have shown insecticidal properties
Economic values
Important commercial fruits from Annona spp. (atemoya, cherimoya, custard-apple, ilarma, sugar-apple, sweet sop, sour sop), Artabotrys.  The Annonaceae are woody trees, shrubs and vines comprising about 130 genera and 2,300 species. The leaves are simple, alternate, lack stipules, and generally are distichously arranged in flat sprays. The flowers are bisexual and actinomorphic, possessing 3 whorls of perianth with 3 segments in each whorl.

Annona spp.
The elongated floral axis also bears many helically disposed stamens and several to many simple pistils. All of the floral parts are distinct. The stamens are very short, consisting of the fertile central anther portion, a distal pad of fleshy connective tissue, and a short fleshy basal portion. The stamens are generally so tightly packed on the receptacle that often only the fleshy connective tissue of each is exposed. The pistils each have a superior ovary with one locule and 1-many parietal ovules. Sectioned seeds reveal channels or partitions in the ruminate endosperm. The pistils generally remain distinct and develop into berry-like fruits but sometimes they coalesce into multiple fruits like the custard apple.

Floral wealth of Mahanadi River