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| Effects of straw addition on increased greenhouse vegetable yield and reduced antibiotic residue in fluvo-aquic soil |
| ZHANG Zhi-qiang, WANG Xiu-bin, LI Chun-hua, HUANG Shao-wen, GAO Wei, TANG Ji-wei, JIN Jiyun |
1、Key Laboratory of Plant Nutrition and Fertilizer, Ministry of Agriculture/Institute of Agricultural Resources and Regional Planning,
Chinese Academy of Agricultural Sciences, Beijing 100081, P.R.China
2、Tianjin Institute of Agricultural Resources and Environment, Tianjin 300192, P.R.China |
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摘要 Organic manure application is an important measure for high yield and good quality vegetable production, whereas organic manure is also a main source of residual antibiotic in soils. A 3-yr experiment was conducted on a fluvo-aguic soil in Tianjin of northern China. The objective of this study was to investigate the effects of different fertilization patterns on yield of six-season vegetables with celery and tomato rotation, and dynamic change of tetracyclines residues in the soil during the sixth growing season (tomato season). The field experiment comprised six treatments depending on the proportion of nitrogen of each type of fertilizer: 4/4 CN (CN, nitrogen in chemical fertilizer), 3/4 CN+1/4 MN (MN, nitrogen in pig manure), 2/4 CN+2/4 MN, 1/4 CN+3/4 MN, 2/4 CN+1/4 MN+1/4 SN (SN, nitrogen in corn straw), and CF (conventional fertilization, the amounts of nitrogen application were 943 and 912 kg N ha–1 for celery and tomato season, respectively). In addition to CF treatment, the amount of nitrogen application in other treatments was greatly reduced and equal (450 and 450 kg N ha–1 for celery and tomato season, respectively). Results showed that the combined application of 3/4 CN+1/4 MN achieved the highest yield and economic benefit in the first four seasons, but addition of straw (2/4 CN+1/4 MN+1/4 SN treatment) performed better in the subsequent two seasons, and the average yields of 2/4 CN+1/4 MN+1/4 SN treatment were respectively higher by 9.9 and 12.8% than those of 4/4 CN treatment, and by 5.6 and 10.5% than those of CF treatment. The residual chlortetracycline (CTC) in manure-amended soil for three consecutive years increased along with the increase of applied amount of pig manure. Under the same amount of pig manure application, content of CTC in straw-amended soil was obviously decreased compared with no straw-amended soil (3/4 CN+1/4 MN treatment), and averagely decreased by 41.9% for four sampling periods in the sixth season. Addition of crop straw facilitated the degradation of CTC in manure-amended soil. As a whole, the conventional fertilization was not the desirable pattern based on yield, economic benefit and environment, the optimal fertilization pattern with the highest yield and profit and the least soil chlortetracycline residue was the treatment of 2/4 CN+1/4 MN+1/4 SN under this experimental condition.
Abstract Organic manure application is an important measure for high yield and good quality vegetable production, whereas organic manure is also a main source of residual antibiotic in soils. A 3-yr experiment was conducted on a fluvo-aguic soil in Tianjin of northern China. The objective of this study was to investigate the effects of different fertilization patterns on yield of six-season vegetables with celery and tomato rotation, and dynamic change of tetracyclines residues in the soil during the sixth growing season (tomato season). The field experiment comprised six treatments depending on the proportion of nitrogen of each type of fertilizer: 4/4 CN (CN, nitrogen in chemical fertilizer), 3/4 CN+1/4 MN (MN, nitrogen in pig manure), 2/4 CN+2/4 MN, 1/4 CN+3/4 MN, 2/4 CN+1/4 MN+1/4 SN (SN, nitrogen in corn straw), and CF (conventional fertilization, the amounts of nitrogen application were 943 and 912 kg N ha–1 for celery and tomato season, respectively). In addition to CF treatment, the amount of nitrogen application in other treatments was greatly reduced and equal (450 and 450 kg N ha–1 for celery and tomato season, respectively). Results showed that the combined application of 3/4 CN+1/4 MN achieved the highest yield and economic benefit in the first four seasons, but addition of straw (2/4 CN+1/4 MN+1/4 SN treatment) performed better in the subsequent two seasons, and the average yields of 2/4 CN+1/4 MN+1/4 SN treatment were respectively higher by 9.9 and 12.8% than those of 4/4 CN treatment, and by 5.6 and 10.5% than those of CF treatment. The residual chlortetracycline (CTC) in manure-amended soil for three consecutive years increased along with the increase of applied amount of pig manure. Under the same amount of pig manure application, content of CTC in straw-amended soil was obviously decreased compared with no straw-amended soil (3/4 CN+1/4 MN treatment), and averagely decreased by 41.9% for four sampling periods in the sixth season. Addition of crop straw facilitated the degradation of CTC in manure-amended soil. As a whole, the conventional fertilization was not the desirable pattern based on yield, economic benefit and environment, the optimal fertilization pattern with the highest yield and profit and the least soil chlortetracycline residue was the treatment of 2/4 CN+1/4 MN+1/4 SN under this experimental condition.
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Received: 27 May 2014
Accepted: 06 July 2015
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| Fund: This research was supported by the China Agriculture Research System (CARS-25-C-11) and the Special Fund for Agro-Scientific Research in the Public Interest, China (201203095). |
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Corresponding Authors:
HUANG Shao-wen, Tel: +86-10-82108662, E-mail: huangshaowen@caas.cn
E-mail: huangshaowen@caas.cn
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| About author: ZHANG Zhi-qiang, Tel: +86-10-82108662, E-mail: zzqcaas@163.com;* These authors contributed equally to this study. |
Cite this article:
ZHANG Zhi-qiang, WANG Xiu-bin, LI Chun-hua, HUANG Shao-wen, GAO Wei, TANG Ji-wei, JIN Jiyun.
2015.
Effects of straw addition on increased greenhouse vegetable yield and reduced antibiotic residue in fluvo-aquic soil. Journal of Integrative Agriculture, 14(7): 1423-1433.
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| Alex G. 2009. Organic alternatives to chemical fertilizer. In:Haimovich A, ed., Catalyst Vol. I. University of Colorado,Colorado, USA. pp. 33-40Alexander T W, Reuter T, Sharma R, Yanke L J, Topp E,McAllister T A 2009. Longitudinal characterization ofresistant Escherichia coli in fecal deposits from cattlefed subtherapeutic levels of antimicrobials. Applied andEnvironment Microbiology, 75, 7125-7134Arikan O A, Mulbry W, Ingram D, Millner P. 2009a. Minimallymanaged composting of beef manure at the pilot scale: Effectof manure pile construction on pile temperature profilesand on the fate of oxytetracycline and chlortetracycline.Bioresource Technology, 100, 4447-4453Arikan O A, Mulbry W, Rice C. 2009b. Management of antibioticresidues from agricultural sources: Use of composting toreduce chlortetracycline residues in beef manure fromtreated animals. Journal of Hazardous Material,164,483-489Blackwell P A, Kay P, Ashauer R, Boxall A B A. 2009. Effects ofagricultural conditions on the leaching behavior of veterinaryantibiotics in soils. Chemosphere, 75, 13-19Boxall A B A, Johnson P, Smith E J, Sinclair C J, Stutt E, LevyL. 2006. Uptake of veterinary medicines from soils intoplants. Journal of Agricultural and Food Chemistry, 163,2288-2297Campagnolo E R, Johnson K R, Karpati A, Rubin C S, KolpinD W, Meyer M T, Esteban J E, Currier R W, Smith K,Thu K M, McGeehin M. 2002. Antimicrobial residues inanimal waste and water resources proximal to large-scaleswine and poultry feeding operations. Science of the TotalEnvironment, 299, 89-95China Agricultural Yearbook Editing Committee. 2013. ChinaAgriculture Yearbook. China Agriculture Press, China. (inChinese)Dai Z G. 2009. Study on nutrient release characteristics of crop residue and effect of crop residue returning on crop yield andsoil fertility. MSc thesis, Huazhong Agricultural University,China. (in Chinese)Dolliver H, Gupta S, Noll S. 2008. Antibiotic degradation duringmanure composting. Journal of Environment Quality, 37,1245-1253Dolliver H, Kumar K, Gupta S. 2007. Sulfamethazine uptake byplants from manure-amended soil. Journal of EnvironmentQuality, 36, 1224-1230Du L F, Liu W K. 2012. Occurrence, fate, and ecotoxicity ofantibiotics in agro-ecosystems. A review. Agronomy forSustainable Development, 32, 309-327Hamscher G. 2009. Veterinary drugs in the environment:Current knowledge and challenges for the future. Journalof Veterinary Pharmacology and Therapeutics, 32, 24-25Hamscher G, Sczesny S, Höper H, Nau H. 2002. Determinationof persistent tetracycline residues in soil fertilized withliquid manure by high-performance liquid chromatographywith electrospray ioniza-tion tandem mass spectrometry.Analytical Chemistry, 74,1509-1518.He D C. 2011. Transfer and cumulation of veterinary tetracyclineantibiotics in cycle agriculture and technology of Interdiction.Ph D thesis, Hunan Agricultural University, China. (inChinese)Hu X G, Zhou Q X, Luo Y. 2010. Occurrence and sourceanalysis of typical veterinary antibiotics in manure, soil,vegetables and groundwater from organic vegetable bases,northern China. Environmental Pollution, 158, 2992-2998Huang X, Li T X, Yu H Y. 2010. Risk assessments of heavymetals in typical greenhouse soils. Plant Nutrition andFertilizer Science, 16, 833-839 (in Chinese)Isitekhale H H E, Osemwota I O, Amhakhian S O. 2013.Poultry manure and NPK fertilizer application and theirresidual effects on the yield and yield components oftomato (Lycopersiconesculentum. Mill) in two distinctecological zones of central southern Nigeria. IOSR Journalof Agriculture and Veterinary Science, 3, 40-47Jones A D, Bruland G L, Agrawal S G, Vasudevan D. 2005.Factors influencing the sorption of oxytetracycline to soils.Environmental Toxicology and Chemistry, 24, 761-770Karc? A, Balc?o?lu I A. 2009. Investigation of the tetracycline,sulfonamide, and fluoroquinolone antimicrobial compoundsin animal manure and agricultural soils in Turkey. Scienceof the Total Environment, 407, 4652-4664Kim K R, Owens G, Kwon S I, So K H, Lee D B, Ok Y S. 2011.Occurrence and environmental fate of veterinary antibioticsin the terrestrial environment. Water Air and Soil Pollution,214, 163-174Kim K R, Owens G, Ok Y S, Park W K, Lee D B, Kwon S I. 2012.Decline in extractable antibiotics in manure-based compostsduring composting. Waste Management, 32, 110-116Kumar K, Gupta S C, Baidoo S K, Chander Y, Rosen C J. 2005.Antibiotic uptake by plants from soil fertilized with animalmanure. Journal of Environment Quality, 34, 2082-2085Kwon S I, Owens G, Ok Y S, Lee D B, Jeon W T, Kim J G,Kim K R. 2011. Applicability of the charm II system formonitoring antibiotic residues in manure-based composts.Waste Management, 31, 39-44Kühne M, Ihnell D, Möller G, Agthe O. 2000. Stability oftetracycline in water and liquid manure. Journal of VeterinaryMedicine (Series A), 47, 379-384Li S T, Liu R L, Shan H. 2009a. Nutrient contents in main animalmanures in China. Journal of Agro-Environment Science,28, 179-184 (in Chinese)Li Y W, Mo C H, Zhao N, Tai Y P, Bao Y P, Wang J Y, Li MY, Liang W M. 2009b. Investigation of sulfonamides andtetracyclines antibiotics in soils from various vegetablefields. Environmental Science, 6, 1762-1766 (in Chinese)Li Z F, Zhang X H, Xia Y Z, Li W Z, Li T F, Yang Q H, Wu BZ. 2007. Research progress on application of improvingtobacco soil fertility by reusing of crop straws. ChineseAgricultural Science Bulletin, 23, 165-170 (in Chinese)Li Z J, Yao Z P, Zhang J, Liang Y C. 2008. A review on fateand ecological toxicity of veterinary antibiotics in soilenvironments. Asian Journal of Ecotoxicology, 3, 15-20(in Chinese)Martínez-Carballo E, González-Barreiro C, Scharf S, GansO. 2007. Environmental monitoring study of selectedveterinary antibiotics in animal manure and soils in Austria.Environmental Pollution, 148, 570-579Masarirambi M T, Mbokazi B M, Wahome P K, Oseni T O. 2012.Effects of kraal manure, chicken manure and inorganicfertilizer on growth and yield of lettuce (Lactuca sativa L.var Commander) in a semi-arid environment. Asian Journalof Agricultural Science, 4, 58-64Mohring S A I, Strzysch I, Fernandes M R, Kiffmeyer T K,Tuerk J, Hamscher G. 2009. Degradation and eliminationof various sulfonamides during anaerobic fermentation:A promising step on the way to sustainable pharmacy?Environmental Science & Technology, 43, 2569-2574Moller K. 2009. Influence of different manuring systems withand without biogas digestion on soil organic matter andnitrogen inputs, flows and budgets in organic croppingsystems. Nutrient Cycling in Agroecosystems, 84, 179-202Ramaswamy J, Prasher S O, Patel R M, Hussain S A, BarringtonS F. 2010. The effect of composting on the degradationof a veterinary pharmaceutical. Bioresource Technology,101, 2294-2299Rottmann N, Dyckmans J, Joergensen R G. 2010. Microbialuse and decomposition of maize leaf straw incubated inpacked soil columns at different depths. European Journalof Soil Biology, 46, 27-33Sarmah A K, Meyer M T, Boxall A B A. 2006. A global perspectiveon the use, sales, exposure pathways, occurrence, fate andeffects of veterinary antibiotics (VAs) in the environment.Chemosphere, 65, 725-759Selvam A, Zhao Z Y, Wong J W C. 2012. Composting ofswine manure spiked with sulfadiazine, chlortetracyclineand ciprofloxacin. Bioresource Technology, 126, 412-417Shen Y, Wei Y S, Zheng J X, Fang Y, Chen L P. 2009.Biodegradation of tetracycline antibiotics residues inswine manure. Chinese Journal of Process Engineering, 9, 962-967 (in Chinese)Suthamathy N, Seran T H. 2013. Residual effect of organicmanure EM Bokashi applied to proceeding crop of vegetablecowpea (Vigna unguiculata) on succeeding crop of radish(Raphanus sativus). Research Journal of AgriculturalScience, 1, 2-5Tai Y P, Mo C H, Li Y W, Wu X L, Duan X Z, Qu X L, HuangX P. 2011.Concentrations and distribution of tetracyclineantibiotics in vegetable field soil chronically fertilized withmanures. Environmental Science, 32, 1182-1187 (inChinese)Tang H, Zhang Y Z, Long H Y, Huang Y X, Liao C L, Li H B.2010. Effect of different fertilization treatments on yieldand nutrients uptake of Chinese cabbage and cabbage.Journal Hunan Agricultural University (Natural Sciences),36, 705-709 (in Chinese)Wang Q, Yates S R. 2008. Laboratory study of oxytetracyclinedegradation kinetics in animal manure and soil. Journal ofAgricultural and Food Chemistry, 56, 1683-1688Wang R, Wei R C, Liu T Z, Wang T. 2009. Residue anddegradation kinetics of chlortetracycline in chicken excreta.Journal of Nanjing Agricultural University, 32, 85-89 (inChinese)Verma B, Headley J V, Robarts R D. 2007. Behaviour and fateof tetracycline in river and wetland waters on the CanadianNorthern Great Plains. Journal of Environmental Scienceand Health, (Part A: Toxic/Hazardous Substances &Environmental Engineering), 42, 109-117Xie Y F, Li X W, Wang J F, Christakos G, Hu M G, An L H, Li FS. 2012. Spatial estimation of antibiotic residues in surfacesoils in a typical intensive vegetable cultivation area inChina. Science of the Total Environment, 430, 126-131Yin C Y, Luo Y M, Teng Y, Zhang H B, Chen Y S, Zhao Y G. 2012.Pollution characteristics and accumulation of antibiotics intypical protected vegetable soils. Environmental Science,33, 2810-2816 (in Chinese)Zhang H M, Zhang M K, Gu G P. 2008. Residues of tetracyclinesin livestock and poultry manures and agricultural soils fromNorth Zhejiang Province. Journal of Ecology and RuralEnvironment, 24, 69-73 (in Chinese)Zhang Z Z, Li CH, Huang S W, Gao W, Tang J W. 2013.Optimization of residual tetracyclines analysis in soils andmanure using SPE-HPLC and pilot survey in Tianjin. PlantNutrition and Fertilizer Science, 19, 713-726 (in Chinese)Zhang S Q, Zhang F D, Liu X M, Wang Y J, Zhang J F.2006. Degradation of antibiotics and passivation of heavymetals during thermophilic composting process. ScientiaAgricultura Sinica, 39, 337-343(in Chinese) |
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