تأثیر عمل‌آوری باگاس نیشکر با ترکیبات قلیایی در زمان‌های مختلف بر ترکیبات شیمیایی، قابلیت هضم و فراسنجه‌های تخمیر شکمبه در شرایط برون‌تنی

نوع مقاله : مقاله پژوهشی

نویسندگان

1 گروه علوم دامی، دانشکده کشاورزی، دانشگاه ایلام، ایلام، ایران

2 دانشگاه ایلام. دانشکده کشاورزی. گروه لوم دامی

چکیده

زمینه مطالعاتی: باگاس نیشکر یکی از محصولات جانبی کارخانجات تولید قند است که حاوی فیبر بالایی می‌باشد و قیمت آن در مقایسه با کاه گندم پایین‌تر است. هدف: بنابراین هدف این آزمایش مطالعه قابلیت هضم ماده خشک و ماده آلی و فراسنجه‌های تخمیر شکمبه‌ای جیره‌های حاوی باگاس نیشکر عمل‌آوری‌شده با ترکیبات قلیایی به روش‌های مختلف در شرایط برون‌تنی بود. روش کار: تیمارهای آزمایش شامل 1- جیره حاوی باگاس عمل‌آوری‌نشده و ذخیره‌شده به مدت 30 روز، 2- جیره حاوی باگاس عمل‌آوری‌شده با محلول اوره 4 درصد و محلول هیدروکسید کلسیم 1 درصد و ذخیره‌شده به مدت 30 روز، 3- جیره حاوی باگاس عمل‌آوری‌شده با محلول اوره 3 درصد و محلول هیدروکسید کلسیم 2 درصد و ذخیره‌شده به مدت 30 روز، 4- جیره حاوی باگاس عمل‌آوری‌نشده و ذخیره‌شده به مدت 45 روز، 5- جیره حاوی باگاس عمل‌آوری‌شده با محلول اوره 4 درصد و محلول هیدروکسید کلسیم 1 درصد و ذخیره‌شده به مدت 45 روز و 6- جیره حاوی باگاس عمل‌آوری‌شده با محلول اوره 3 درصد و محلول هیدروکسید کلسیم 2 درصد و ذخیره‌شده به مدت 45 روز بودند. داده‌های ترکیبات شیمیایی، قابلیت‌هضم ماده خشک و ماده آلی و آزمایش مؤلفه‌های تولید گاز به‌صورت فاکتوریل 3×2 در قالب طرح کاملا تصادفی، آنالیز آماری شدند. نتایج: بالاترین درصد ماده خشک در تیمار 4 مشاهده شد (05/0P<). بیشترین و کمترین درصد ماده آلی به ترتیب در تیمار 1و 6 مشاهده شد (05/0P<). تیمار 6 در مقایسه با سایر تیمارها تولید گاز تجمعی 96 ساعت و پتانسیل تولید گاز بیشتری داشت (05/0P<). نتیجه‌گیری نهایی: به طور کلی، عمل‌آوری باگاس با محلول اوره 3 درصد و هیدروکسید کلسیم 2 درصد و ذخیره‌شده به مدت 30 روز (تیمار 3) سبب بهبود قابلیت‌هضم ماده آلی و افزایش تولید گاز شد. بنابراین از این روش می‌توان برای بهبود ارزش غذایی باگاس نیشکر در جیره حیوانات نشخوارکننده استفاده کرد.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Effect of sugarcane bagasse processing with alkalin compounds at different times on chemical compositions, digestibility and rumen fermentation parameters in vitro

نویسندگان [English]

  • fatemeh Jafarian 1
  • farshid fatahnia 1
  • saiedreza mousavi 1
  • Mohammad Shamsollahi 2
  • parisa darat 1
1 Department of Animal Science, Faculty of Agriculture, Ilam University, Ilam, Iran
2 Department of Agricultur Group of Animal Science . Ilam University
چکیده [English]

Introduction: Due to reduced rainfall and degradation of rangelands, some portion of ruminant feed is provided by agricultural by-products such as cereal straws and sugarcan bagasse (SB). A key strategy for achieving environmentally sustainable added value and providing animal feed is to convert agricultural by-products into animal feed (Madadi et al 2023). Sugarcane is one of the most important economic crops worldwide and is mostly used as a raw material in the sugar industry and it is produced in more than 100 countries around the world. Its biomass can be used as animal feed in many countries more than any other forage. The SB is one of the fiberous residues that remain after water extraction from the sugarcane stalk and can be used as a source of fodder for ruminants (Pipitpukdee et al 2020). However, it has been reported that these by-products have low protein (less than 3% on DM basis), high cellulose (more than 40% on DM basis), high hemicellulose (more than 35% on DM basis), high lignin (15% on DM basis), and low DM digestibility (20-30%; Ahmed et al., 2013; Costa et al., 2013). Some livestock producers use unprocessed SB in ruminant nutrition, which is not accompanied by desirable results on animal performance (Nogueira et al 2022; Kraiprom et al 2022). Various methods including physical, chemical, and biological processing are used to change the physical and chemical nature of SB to improve its digestibility (Balgees et al 2007; Rezaii et al 2022; Khawar et al 2023). Therfore, the aim of this experiment was to investigate dry matter (DM) and organic matter (OM) digestibility and in vitro ruminal feremrntation parameters of diets containing sugarcan bagasse (SB) treated with urea (U) calcium hydroxide (CaH) at different times. Materials and methods: For each processing method, 6 one-kilogram samples of sugarcane bagasse were considered. One liter of solution was added to each kilogram of sugarcane bagasse and mixed thoroughly. Also, 6 one-kilogram samples of bagasse were considered as controls (without processing), and each was mixed with one liter of water without urea or calcium hydroxide. All samples inside 2-layer nylons were well compressed and sealed. Then, 3 one-kilogram samples of sugarcane bagasse mixed with alkaline solution and 3 control samples were silaged for 30 days and the rest for 45 days at room temperature. After the end of the desired time, the samples were taken out of the nylon and exposed to air for 5 days and stored for chemical analysis after drying. Then, experimental diets were prepared using these processed sugarcane bagasse samples.The SB was treated with solution containing different content of urea (4 or 3%) and calcium hydroxide (1 or 2%) for two times (30 or 45 days). Then, experimental diets were formulated by using treated SB. Experimental diets were 1- diet containing untreated SB stored for 30 days (Control, C-30), 2- diet containing treated SB with 4% U and 1% CaH stored for 30 d (U4CaH1-30), 3- diet containing treated SB with 3% U and 2% CaH solution stored for 30 d (U3CaH2-30), 4- diet containing untreated SB stored for 45 d (C-45), 5- diet containing treated SB with 4% U and 1% CaH stored for 45 d (U4CaH2-30), and 6- diet containing treated SB with 3% U and 2% CaH solution stored for 45 d (U3CaH2-45). Ingredients and chemical composition of experimental diets are shown in Table 1 and 2, respectively. The SB treated with different methods at different times and experimental diets were dried in an oven at 60 ° C for 48 hours, ground through a 1-mm screen using a Wiley mill, and analysed for dry matter (DM), organic matter (OM), crude protein (CP) (AOAC 2007), neutral detergent fibre (NDF) and acid detergent fibre (ADF) (Van Soest et al 1991). For measurement of methane production, the final gas production (end of 24 hours) was recorded after 24 hours of incubation of the sample in ruminal fluid + phosphate buffer. Experiment conducted by gas production technique (Menke and Steingass 1988) based on completely randomized design as 2×3 factorial. Results and discussion: The effect of different processing methods at different times on chemical composition of SB is shown in Table 3. Results showed that the highest DM content was observed in C-45 (P<0.05). Whereas, SB treated with 3% U and 2% CaH and preserved for 35 or 45 d had lower DM content compared to others (P<0.05). The highest and the lowest OM content were observed in SB untreated and preserved for 30 d and SB treated with 3% U and 2% CaH and preserved for 45 d, respectively (P<0.05). Treatment of SB with U and CaH increased crude protein (CP) content compared untreated SB (P<0.05). The SB treated with U and CaH and preserved for 30 or 45 d had lower neutral detergent fiber (NDF) compared to untreated SB (P<0.05). The highest ash content was observed in SB treated with 3% U and 2% CaH and preserved for 45 d (P<0.05). Ruminal fermentation parameters of diets containing SB processed by different methods at different times is shown in Table 4. The lowest 24 h comulative gas production (CGP) and OM digestibility were observed in C-30 and C-45 diets (P<0.05). Methan production, patitioning factor, efficiency of microbial mass production and DM digestibility did not influence by experimental diets (P>0.05). Gas production parameters of diets containing SB processed by different methods at different times are shown in Table 5. The U3CaH2-45 diet had higher 96 h CGP and gas production potential than other diets (P<0.05). The U3CaH2-30 and U3CaH2-45 had the lowest lag time (P<0.05). Diets containing SB processed with 3% urea solution and 2% calcium hydroxide solution and stored for 30 and 45 days had the highest cumulative gas production (P<0.05). Conclusion: In general, treatment of SB with 3% U and 2% CaH solution improved OM digestibility and gas production and can be used as a method for improvement of nutritional value of SB for using in diets of ruminant animals.

کلیدواژه‌ها [English]

  • Sugarcan bagasse
  • Treatment
  • Urea
  • Calcium hydroxide
  • Dry matter and irganic matter digestibility
  • Ruminal fermentation

مراجع

Ahmed M H, Babiker S A, Fadel Elseed A E M A and Mohammed A M, 2013. Effect of urea-treatment on nutritive value of sugarcane bagasse. ARPN Journal of Science and Technology 3(8): 834-838.
Alemzadeh B, Noroozi S and Kardooni A, 2001. Determination of nutritive value and apparent digestibility in Bagasse and treated Bagasse. Pajouhesh and Sazandegi 53: 14-17. (In Persian)
AOAC, 2007. Official Methods of Analysis. 15th ed. Association of Official Analytical Chemists. Arlin, VA, USA, 1230 pp.
Babaei M, Ghanbari F, Ashour Mohammad Q and Bayat Kohsar J, 2016. Effects of electron beam, hydrogen peroxide and hydrobromic acid treatment on the nutritional value of mung bean residues. Iranian Animal Science Research 8(3): 441-454. (In Persian).
Balgees A, Elmnan A, Elseed A F and Salih A M, 2007. Effect of ammonia and urea treatments on the chemical composition and rumen degradability of bagasse. The Journal of Applied Sciences Research 3: 1359-1362.
Balgees A, Elmnan A, Hemeedan A A and Ahmed R I, 2015. Influence of different treatments on nutritive values of sugarcane bagasse. Global Journl of Animal Science Reserch 2(3): 295-231.
Barlianti V, Dahnum D, Hendarsyah H and Abimanyu H, 2015. Effect of alkaline pretreatment on properties of lignocellulosic oil palm waste. Procedia Chemistry 16: 195-201.
Berger L L, Klopfenstein T J and Britton R A, 1990. Britton. Factors causing greater in vitro than in vivo digestibility of sodium hydroxide treated roughages. Animal Feed Science Technology 29: 73-87.
Blümmel M, Aiple K P., Steingaβ H and Becker K, 1999. A note on the stoichiometrical relationship of short chain fatty acid production and gas formation in vitro in feedstuffs of widely differing quality. Journal of Animal Physiology and Animal Nutrition 81(3): 157-167.
Blummel M, Makkar P S and Becker K, 1997. In vitro gas production: a technique revisited. Journal of. Animal Physiology and Animal Nutrition 77: 24-34.
Carvalho G G P D, Garcia R, Pires A J V, Silva R R, Detmann E, Eustaquio Filho A and Carvalho L M, 2013. Diets based on sugar cane treated with calcium oxide for lambs. Asian-Australasian Journal of Animal Sciences 26(2): 218-226.
Castañón-Rodríguez J F, Welti-Chanes J, Palacios A J, Torrestiana-Sanchez B, Ramírez de León J A, Velázquez G, and Aguilar-Uscanga M G, 2015. Influence of high pressure processing and alkaline treatment on sugarcane bagasse hydrolysis. CyTA-Journal of Food 13(4): 613-620.
Costa S M, Mazzola P G, Silva J C, Pahl R, Pessoa Jr A and Costa S A, 2013. Use of sugar cane straw as a source of cellulose for textile fiber production. Industrial Crops and Products 42: 189-194.
Dehghani M, Afzalzadeh A and Norouzian M A, 2021. The study of chemical composition and ruminal degradability parameters of urea treatment of wheat straw and sugarcane bagasse. Animal Production 23(2): 191-200. (In Persian).
Gunun N, Wanapat M, Gunun P, Cherdthong A, Khejornsart P and Kang S, 2016. Effect of treating sugarcane bagasse with urea and calcium hydroxide on feed intake, digestibility, and rumen fermentation in beef cattle. Tropical Animal Health and Production 48: 1123-1128.
Hameed A A, Salih M A and El-Seed F, 2012. Effect of urea treatment on the chemical composition and rumen degradability of groundnut hull. Pakistan Journal of Nutrition 11: 1146-1151.
Jiang D, Ge X, Zhang Q, Zhou X, Chen Z, Keener H, and Li Y, 2017. Comparison of sodium hydroxide and calcium hydroxide pretreatments of giant reed for enhanced enzymatic digestibility and methane production. Bioresource Technology 244: 1150-1157.
Khawar A, Khan N, Iqbal K J, Fatima M, Rasool F, Anjum K M and Asghar M, 2024. Effect of Urea Treated Sugarcane Bagasse on Growth, Proximate Composition, Microbial Flora and Digestive Enzymes Activities of Grass Carp (Ctenopharyngodon idella). Pakistan Journal of Zoology 56(5): 2369.
Kraiprom T, Jantarat S, Yaemkong S, Cherdthong A and Incharoen T, 2022. Feeding Thai native sheep molasses either alone or in combination with urea-fermented sugarcane bagasse: the effects on nutrient digestibility, rumen fermentation, and hematological parameters. Veterinary Sciences 9(8): 415.
Madadi M, Nazar M, Shah S W A, Li N, Imtiaz M, Zhong Z, and Zhu D, 2023. Green alkaline fractionation of sugarcane bagasse at cold temperature improves digestibility and delignification without the washing processes and release of hazardous waste. Industrial Crops and Products 200: 116815.
Manyuchi B, Ørskov E R and Kay R N B, 1992. Effects of feeding small amounts of ammonia treated straw on degradation rate and intake of untreated straw. Animal Feed Science and Technology 38(4): 293-304.
McDonald P, Edwards R, Greenhalgh J F D, Morgan C, Sinclair L A and Wilkinson R G, 2022. Animal Nutriton. Eighth edition, Pearson.
Menke K H and Steingass H, 1988. Estimation of the energetic feed value obtained from chemical analysis and gas production using rumen fluid. Animal Reserch Development 28: 7-55.
NRC, 2007. Nutrient requirements of small ruminants: sheep, goats, cervids and new camelids.
Nogueira N D, Narciso C R P, Felix A D L and Mendes R F, 2022. Pressing temperature effect on the properties of medium density particleboard made with sugarcane bagasse and plastic bags. Materials Research 25: e20210491.
Pipitpukdee S, Attavanich W and Bejranonda S, 2020. Climate change impacts on sugarcane production in Thailand. Atmosphere 11(4): 1-15.
Rezaii F, Bayatkouhsar J, Ghanbari F, and Arab F, 2023. The effect of water, urea, sodium hydroxide, and hydrogen peroxide processing on the cumin residues animal digestibility. International Journal of Recycling of Organic Waste in Agriculture 12(4): 525-537.
Rezende C A, De Lima M A, Maziero P, deAzevedo E R, Garcia W and Polikarpov I, 2011. Chemical and morphological characterization of sugarcane bagasse submitted to a delignification process for enhanced enzymatic digestibility. Biotechnology for Biofuels 4: 1-19.
Ribeiro G O, Gruninger R J, Jones D R, Beauchemin K A, Yang W Z, Wang Y and McAllister T A, 2020. Effect of ammonia fiber expansion-treated wheat straw and a recombinant fibrolytic enzyme on rumen microbiota and fermentation parameters, total tract digestibility, and performance of lambs. Journal of Animal Science 98(5): 1-19.
Sahnoune S, Besle J M, Chenost M, Jouany J P and Combes D, 1991. Treatment of straw with urea. 1. Ureolysis in a low water medium. Animal Feed Science and Technology 34(1-2): 75-93.
Sallam S M A, Nasser M E A, El-Waziry A M, Bueno I C D S and Abdalla A L, 2007. Use of an in vitro rumen gas production technique to evaluate some ruminant feedstuffs. Journal of Applid. Science. Reserch 3(1): 34-41.
Sambusiti C, Monlau F, Ficara E, Carrère H and Malpei F, 2013. A comparison of different pre-treatments to increase methane production from two agricultural substrates. Applied Energy 104: 62-70.
SAS, 2006. Procedures Guide, second ed. SAS Institute Inc., Cary, NC, USA.
Selim A S M, Pan J, Takano T, Suzuki T, Koike S, Kobayashi Y and Tanaka K, 2004. Effect of ammonia treatment on physical strength of rice straw, distribution of straw particles and particle-associated bacteria in sheep rumen. Animal Feed Science and Technology 115(1-2): 117-128.
Shetty D J, Kshirsagar P, Tapadia-Maheshwari S, Lanjekar V, Singh S K and Dhakephalkar P K, 2017. Alkali pretreatment at ambient temperature: A promising method to enhance biomethanation of rice straw. Bioresource Technology 226: 80-88.
So S, Cherdthong A and Wanapat M, 2022. Growth performances, nutrient digestibility, ruminal fermentation and energy partition of Thai native steers fed exclusive rice straw and fermented sugarcane bagasse with Lactobacillus, cellulase and molasses. Journal of Animal Physiology and Animal Nutrition 106(1): 45-54.
Soltani Naseri K, Ghanbari F, Bayat Kouhsar J and Taliey F, 2018. Effect of chemical and biological processing methods on chemical composition, gas production parameters and in vitro digestibility of cicer Arietinum wastes. Research on Animal Production 9(22): 72-82.
Sommart K, Parker D S, Rowlinson P and Wanapat M, 2000. Fermentation characteristics and microbial protein synthesis in an in vitro system using cassava, rice straw and dried ruzi grass as substrates. Asian-Australasian Journal of Animal Sciences 13(8): 1084-1093.
Theander O, Aman p, Sundstol F and Owen E, 1984. Straw and other by-products as feed. Elseveir, Amisterdam 45.
Van Soest P J, 1994. Nutritional ecology of the ruminant, second ed. Cornell University Press, Ithaca, NY.
Van Soest P J, Robertson J B and Lewis B A, 1991. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science 74(10): 3583-3597.
Wanapat M, Polyorach S, Boonnop K, Mapato C and Cherdthong A, 2009. Effects of treating rice straw with urea or urea and calcium hydroxide upon intake, digestibility, rumen fermentation and milk yield of dairy cows. Livestock Science 125: 238-243.
Yalchi T, Kargar S, Khorvash M and Ghorbani G R, 2012. Effect of sodium hydroxide on chemical compositions and in vitro digestibility of soybean straw. In 3th Iranian Animal Science Congresspp. 1069-1073.
Zhang J, Kong C, Yang M and Zang L, 2020. Comparison of calcium oxide and calcium peroxide pretreatments of wheat straw for improving biohydrogen production. ACS Omega 5(16): 9151-9161.
پژوهش های علوم دامی (دانش کشاورزی)
دوره 35، شماره 4
اسفند 1404
صفحه 47-64

فایل ها

سابقه مقاله

  • تاریخ دریافت: 26 اسفند 1403
  • تاریخ بازنگری: 08 مرداد 1404
  • تاریخ پذیرش: 03 شهریور 1404

هم رسانی

ارجاع به این مقاله

آمار