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The Effects of Different Carbon Dioxide Doses on Yield and Nutritional Values of Hydroponic Wheat (Triticum aestivum L.) Grass Juice

Year 2015, Volume: 1 Issue: 2, 78 - 84, 19.11.2015

Abstract

This research has been conducted in the conditioning chamber of  Karabük University Eskipazar Vocational School Department Crop and Animal Production between the dates of 5.01.2015 and 01.08.2015 in order to identify the effects of different carbon dioxide doses on yield and nutritional values of hydroponic wheat (Triticum aestivum L.) grass juice. In the research, three different carbon dioxide doses (Control; 0, D1; 750, D2; 1500, D3; 2000 ppm) have been applied to growth medium and their effects on the content of plant yield seed rate, plant and grass yield, grass juice yield and pH, plant height and root length, plant and grass dry matter content, grass juice energy and macronutrient values (moisture, protein, carbohydrate, fat, dietary fiber and ash) and minerals (N, P, K, Ca, Mg, Fe, Cu, Mn, Zn and Na) have been analyzed. According to results, the highest plant, grass and grass juice yield and plant height values were acquired from D1 practice. While the highest and root length was obtained from D1 and D3 treatments, the highest plant dry matter content was obtained from control, D2 and D3 practices. The highest fat, Ca and Fe contents were obtained from D3 practice. While the highest Mn contents were obtained from control and D3 practices, the highest Mg contents were obtained from D1, D2 and D3 practices. The highest Na content was obtained from control and D1 practices. D1 practices can be recommandable to achieve only the highest grass and grass juice yield.

References

  • Ainsworth EA., Beier C., Calfapietra C., Ceulemans R., Durand-Tardif M., Farquhar GD., Godbold DL., Hendrey GR., Hickler T., Kaduk J., et al., 2008. Next Generation of
  • Elevated [CO2] Experiments with crops: a critical investment for feeding the future world. Plant, Cell and Environment, 31: 1317-1324.
  • Allen LH and Vara Prasad PV., 2004. Crop responses to elevated carbon dioxide. Encyclopedia of Plant and Crop Science, 346-348.
  • Amthor JS., 2001. Effects of atmospheric CO2 concentration on wheat yield: review of results from experiments using various approaches to control CO2 concentration. Field Crops Research, 73: 1-34.
  • Ashish S., Shilpa K., Singh RR., Sanjav K and Rajendran N., 2012. Wheatgrass: an alternative household nutritional food security. International Research Journal of Pharmacy, 3(7): 246-250.
  • Ashok SA., 2011. Phytochemical and pharmacological screening of wheatgrass juice (Triticum aestivum L.). International Journal of Pharmaceutical Sciences Review and Research, 9(1): 159-165.
  • Bar-Sela G., Tsalic M., Fried G and Goldberg H., 2007. Wheat grass juice may improve hematological toxicity related to chemotherapy in breast cancer patients: a pilot study. Nutrition and Cancer, 58(1): 43-48.
  • Bonfili L., Amici M., Cecarini V., Cuccioloni M., Tacconi R., Angeletti M., Fioretti E., Keller JN and Eleuteri AM., 2009. Wheat sprout extract-induced apoptosis in human cancer cells by proteasomes modulation. Biochimie, 91: 1131-1144.
  • Chytyk CJ., 2010. Leaf photosynthesis in wheat (Triticum spp.) under conditions of low temperature and CO2 enrichment. A Thesis Master of Science, University of Saskatchewan Department of Biochemistry, Saskatoon, P. 90.
  • Degraff Loraine R., 2011. The Complete Guide to Growing and Using Wheatgrass: Everything You Need to Know
  • Explained Simply-Including Easy to Make Recipes. Atlantic Publishing Group Inc, Florida.
  • Dubey SK., Tripathi SK and Pranuthi G., 2014. Impact of elevated CO2 on growth and yield of wheat crop: a review. International Journal of Agriculture, Environment & Biotechnology, 7(3): 581-594.
  • Dung DD., Godwin IR and Nolan JV., 2010. Nutrient content and in sacco digestibility of barley grain and sprouted barley. Journal of Animal and Veterinary Advances, 9(19): 2485-2492.
  • Falcioni G., Fedeli D., Tiano L., Calzuola I., Mancinelli L., Marsili V and Gianfranceschi G., 2002. Antioxidant activity of wheat sprouts extract in vitro: inhibition of DNA oxidative damage. Journal of Food Science, 67(8): 2918-2922.
  • Fazaeli H., Golmohammadi HA, Tabatabayee SN and Asgari-Tabrizi M., 2012. Productivity and nutritive value of barley gren fodder yield in hydroponic system. World Applied Science Journal, 16(4): 531-539.
  • Hamid N., Jawaid F and Amin D., 2009. Effect of short-term exposure to two different carbon dioxide concentrations on growth and some biochemical parameters of edible beans (Vigna radiata and Vigna unguiculata). Pakistan Journal of Botany, 41(4): 1831-1836.
  • JMP., 2007. Statistic and Graphics Guide, Release 7, SAS Institute Inc., Cary, USA.
  • Kapur B., 2010. Artan CO2 ve küresel iklim değişikliğinin çukurova bölgesinde buğday verimliliği üzerine etkileri. Doktora Tezi (Basılmamış). Çukurova Üniversitesi Fen Bilimleri Enstitüsü, Adana.
  • Karaşahin M., 2014. Hidroponik ortamda yeşil yem üretimi. Harman Time Dergisi, 12: 2-4.
  • Kimball BA and Idso SB., 1983. Increasing atmospheric CO2: effects on crop yield water use and climate. Agricultural Water Management, 7: 55-72.
  • Lam SK., Norton R., Armstrong R and Chen D., 2010. Effect of Elevated Carbon Dioxide on 15N-Fertilizer Recovery Under Wheat in Australia. 19th World Congress of Soil Science, Soil Solutions for a Changing World. 1-6 August 2010, Brisbane, Australia, 25-28.
  • Marwaha RK., Bansal D., Kaur S and Trehan A., 2004. Wheat grass juice reduces transfusion requirement in patients with thalassemia major: a pilot study. Indian Pediatrics, 41: 717-720.
  • Mujoriya R and Bodla RB., 2011. A study on wheat grass and its nutritional value. Food Science and Quality Management, 2: 1-8.
  • Patel Janki B and Patel Piyush M., 2013. Anticancer and cytotoxic potantial of Triticum aestivum extract on hela cell line. International Research Journal of Pharmacy, 4(1):103-105.
  • Rana S., Kamboj JK and Gandhi V., 2011. Living life the natural way - wheatgrass and health. Functional Foods in Health and Disease, 1(11): 444-456.
  • Rattanapichai W and Klem K., 2014. Interactive effects of elevated CO2 concentration, nitrogen nutrition and uv-exclusion on yield, aboveground biomass and root development in winter wheat and spring barley. Mendelnet, 95-100.
  • Reuveni J and Bugbee B., 1997. Very high C02 reduces photosynthesis, dark respiration and yield in wheat. Annals of Botany, 80: 539-546.
  • Rodriguez-De Lara R., Herrera-Corredor CA., Fallas-Lopez M., Rangel-Santos R., Mariscal-Aguayo V., Martinez-Hernandez PA and Garcia-Muniz JG., 2007. Influence of supplemental dietary sprouted wheat on reproduction in artificially inseminated doe rabbits. Animal Reproduction Science, 99: 145-155.
  • Shah KV., Kapupara PK and Desai TR., 2011. Determination of sodium, potassium, calcium and lithium in a wheat grass by flame photometry. Pharma Science Monitor An International Journal of Pharmaceutical Sciences, 900-909.
  • Shukla V., Vashistha M and Singh SN., 2009. Evaluation of antioxidant profile and activity of amalaki (Emblica officinalis), spirulina and wheat grass. Indian Journal of Clinical Biochemistry, 24(1): 70-75.
  • Singh N., Verma P and Pandey BR., 2012. Therapeutic potential of organic Triticum aestivum Linn. (wheat grass) in prevention and treatment of chronic diseases: an overview. International Journal of Pharmaceutical Sciences and Drug Research, 4(1): 10-14.
  • Stitt M and Krapp A., 1999. The interaction between elevated carbon dioxide and nitrogen nutrition: the physiological and molecular background. Plant, Cell and Environment, 22: 583-621.
  • Tremblay N and Gosselin A., 1998. Effect of carbon dioxide enrichment and light. Hort Technology, 8(4): 1-5.

Farklı Karbondioksit Dozlarının Hidroponik Buğday (Triticum aestivum L.) Çim Suyunun Verim ve Besin Değerleri Üzerine Etkileri

Year 2015, Volume: 1 Issue: 2, 78 - 84, 19.11.2015

Abstract

dozda karbondioksit uygulamalarının çim suyu verim ve besin değerleri üzerine etkilerini belirlemek amacıyla 01.03.2015 ile 01.08.2015 tarihleri arasında Karabük Üniversitesi Eskipazar Meslek Yüksekokulu Bitkisel ve Hayvansal Üretim Bölümü iklimlendirme odasında yürütülmüştür. Çalışmada; üç farklı karbondioksit dozu (Kontrol; 0, D1; 750, D2; 1500 ve D3; 2000 ppm) yetiştirme ortamına uygulanarak, bitki verimi tohum oranı, bitki ve çim verimi, çim suyu verimi ve pH, bitki boyu ve kök uzunluğu, bitki ve çim kuru madde oranları, çim suyu enerji ve makro besin değerleri (rutubet, karbonhidrat, protein, yağ, diyet lif ve kül) ile mineral madde (N, P, K, Ca, Mg, Fe, Cu, Mn, Zn ve Na) içerikleri üzerine etkileri araştırılmıştır. Araştırma sonuçlarına göre en yüksek bitki, çim ve çim suyu verimleri ile bitki boyu değerleri D1 uygulamasından elde edilmiştir. En yüksek kök uzunluğu değerleri D1 ve D3 uygulamalarından elde edilirken, en yüksek bitki kuru madde oranı değerleri kontrol, D2 ve D3 uygulamalarından elde edilmiştir. En yüksek yağ, Ca ve Fe içerikleri ise D3 uygulamasından elde edilmiştir. En yüksek Mn içerikleri kontrol ve D3 uygulamalarından elde edilirken, en yüksek Mg içerikleri D1, D2 ve D3 uygulamalarından elde edilmiştir. En yüksek Na içerikleri ise kontrol ve D1 uygulamalarından elde edilmiştir. Sadece en yüksek çim ve çim suyu verim değerleri elde etmek için D1 uygulaması tavsiye edilebilir niteliktedir.

References

  • Ainsworth EA., Beier C., Calfapietra C., Ceulemans R., Durand-Tardif M., Farquhar GD., Godbold DL., Hendrey GR., Hickler T., Kaduk J., et al., 2008. Next Generation of
  • Elevated [CO2] Experiments with crops: a critical investment for feeding the future world. Plant, Cell and Environment, 31: 1317-1324.
  • Allen LH and Vara Prasad PV., 2004. Crop responses to elevated carbon dioxide. Encyclopedia of Plant and Crop Science, 346-348.
  • Amthor JS., 2001. Effects of atmospheric CO2 concentration on wheat yield: review of results from experiments using various approaches to control CO2 concentration. Field Crops Research, 73: 1-34.
  • Ashish S., Shilpa K., Singh RR., Sanjav K and Rajendran N., 2012. Wheatgrass: an alternative household nutritional food security. International Research Journal of Pharmacy, 3(7): 246-250.
  • Ashok SA., 2011. Phytochemical and pharmacological screening of wheatgrass juice (Triticum aestivum L.). International Journal of Pharmaceutical Sciences Review and Research, 9(1): 159-165.
  • Bar-Sela G., Tsalic M., Fried G and Goldberg H., 2007. Wheat grass juice may improve hematological toxicity related to chemotherapy in breast cancer patients: a pilot study. Nutrition and Cancer, 58(1): 43-48.
  • Bonfili L., Amici M., Cecarini V., Cuccioloni M., Tacconi R., Angeletti M., Fioretti E., Keller JN and Eleuteri AM., 2009. Wheat sprout extract-induced apoptosis in human cancer cells by proteasomes modulation. Biochimie, 91: 1131-1144.
  • Chytyk CJ., 2010. Leaf photosynthesis in wheat (Triticum spp.) under conditions of low temperature and CO2 enrichment. A Thesis Master of Science, University of Saskatchewan Department of Biochemistry, Saskatoon, P. 90.
  • Degraff Loraine R., 2011. The Complete Guide to Growing and Using Wheatgrass: Everything You Need to Know
  • Explained Simply-Including Easy to Make Recipes. Atlantic Publishing Group Inc, Florida.
  • Dubey SK., Tripathi SK and Pranuthi G., 2014. Impact of elevated CO2 on growth and yield of wheat crop: a review. International Journal of Agriculture, Environment & Biotechnology, 7(3): 581-594.
  • Dung DD., Godwin IR and Nolan JV., 2010. Nutrient content and in sacco digestibility of barley grain and sprouted barley. Journal of Animal and Veterinary Advances, 9(19): 2485-2492.
  • Falcioni G., Fedeli D., Tiano L., Calzuola I., Mancinelli L., Marsili V and Gianfranceschi G., 2002. Antioxidant activity of wheat sprouts extract in vitro: inhibition of DNA oxidative damage. Journal of Food Science, 67(8): 2918-2922.
  • Fazaeli H., Golmohammadi HA, Tabatabayee SN and Asgari-Tabrizi M., 2012. Productivity and nutritive value of barley gren fodder yield in hydroponic system. World Applied Science Journal, 16(4): 531-539.
  • Hamid N., Jawaid F and Amin D., 2009. Effect of short-term exposure to two different carbon dioxide concentrations on growth and some biochemical parameters of edible beans (Vigna radiata and Vigna unguiculata). Pakistan Journal of Botany, 41(4): 1831-1836.
  • JMP., 2007. Statistic and Graphics Guide, Release 7, SAS Institute Inc., Cary, USA.
  • Kapur B., 2010. Artan CO2 ve küresel iklim değişikliğinin çukurova bölgesinde buğday verimliliği üzerine etkileri. Doktora Tezi (Basılmamış). Çukurova Üniversitesi Fen Bilimleri Enstitüsü, Adana.
  • Karaşahin M., 2014. Hidroponik ortamda yeşil yem üretimi. Harman Time Dergisi, 12: 2-4.
  • Kimball BA and Idso SB., 1983. Increasing atmospheric CO2: effects on crop yield water use and climate. Agricultural Water Management, 7: 55-72.
  • Lam SK., Norton R., Armstrong R and Chen D., 2010. Effect of Elevated Carbon Dioxide on 15N-Fertilizer Recovery Under Wheat in Australia. 19th World Congress of Soil Science, Soil Solutions for a Changing World. 1-6 August 2010, Brisbane, Australia, 25-28.
  • Marwaha RK., Bansal D., Kaur S and Trehan A., 2004. Wheat grass juice reduces transfusion requirement in patients with thalassemia major: a pilot study. Indian Pediatrics, 41: 717-720.
  • Mujoriya R and Bodla RB., 2011. A study on wheat grass and its nutritional value. Food Science and Quality Management, 2: 1-8.
  • Patel Janki B and Patel Piyush M., 2013. Anticancer and cytotoxic potantial of Triticum aestivum extract on hela cell line. International Research Journal of Pharmacy, 4(1):103-105.
  • Rana S., Kamboj JK and Gandhi V., 2011. Living life the natural way - wheatgrass and health. Functional Foods in Health and Disease, 1(11): 444-456.
  • Rattanapichai W and Klem K., 2014. Interactive effects of elevated CO2 concentration, nitrogen nutrition and uv-exclusion on yield, aboveground biomass and root development in winter wheat and spring barley. Mendelnet, 95-100.
  • Reuveni J and Bugbee B., 1997. Very high C02 reduces photosynthesis, dark respiration and yield in wheat. Annals of Botany, 80: 539-546.
  • Rodriguez-De Lara R., Herrera-Corredor CA., Fallas-Lopez M., Rangel-Santos R., Mariscal-Aguayo V., Martinez-Hernandez PA and Garcia-Muniz JG., 2007. Influence of supplemental dietary sprouted wheat on reproduction in artificially inseminated doe rabbits. Animal Reproduction Science, 99: 145-155.
  • Shah KV., Kapupara PK and Desai TR., 2011. Determination of sodium, potassium, calcium and lithium in a wheat grass by flame photometry. Pharma Science Monitor An International Journal of Pharmaceutical Sciences, 900-909.
  • Shukla V., Vashistha M and Singh SN., 2009. Evaluation of antioxidant profile and activity of amalaki (Emblica officinalis), spirulina and wheat grass. Indian Journal of Clinical Biochemistry, 24(1): 70-75.
  • Singh N., Verma P and Pandey BR., 2012. Therapeutic potential of organic Triticum aestivum Linn. (wheat grass) in prevention and treatment of chronic diseases: an overview. International Journal of Pharmaceutical Sciences and Drug Research, 4(1): 10-14.
  • Stitt M and Krapp A., 1999. The interaction between elevated carbon dioxide and nitrogen nutrition: the physiological and molecular background. Plant, Cell and Environment, 22: 583-621.
  • Tremblay N and Gosselin A., 1998. Effect of carbon dioxide enrichment and light. Hort Technology, 8(4): 1-5.
There are 33 citations in total.

Details

Journal Section Tarla Bitkileri
Authors

Muhammet Karaşahin This is me

Publication Date November 19, 2015
Submission Date August 18, 2015
Published in Issue Year 2015 Volume: 1 Issue: 2

Cite

APA Karaşahin, M. (2015). The Effects of Different Carbon Dioxide Doses on Yield and Nutritional Values of Hydroponic Wheat (Triticum aestivum L.) Grass Juice. International Journal of Agricultural and Wildlife Sciences, 1(2), 78-84.

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