Biodegradation Behavior of Starch in Simulated White Water System of Old Corrugated Cardboard Pulping Process

Considering the serious barriers/issues induced by the accumulated starch generated in white water system of old corrugated cardboard(OCC)pulping process,large amounts of accumulated starch in white water would be decomposed by microorganisms and could not be utilized,thereby resulting in severe resource wastage and environmental pollution.This study mainly explored the effects of biodegradation/hydrolysis conditions of the two types of starch substrates(native starch and enzymatically(α-amylase)hydrolyzed starch),which were treated via microorganism degradation within the simulated white water from OCC pulping system and their biodegradation products on the key properties were characterized via X-ray diffraction(XRD),Fourier-transform infrared spectroscopy(FT-IR),and gel permeation chromatography(GPC)technologies.The effects of system temperature,pH value,starch concentration,and biodegradation time on starch biodegradation ratio and the characteristics of obtained biodegradated products from the two types of starches were studied.In addition,the effect ofα-amylase dosage on the biodegradation ratio of enzymatically hydrolyzed starch and its properties was investigated.It was found that the native starch presented a maximal degradation ratio at a system temperature of 55℃and pH value range of 5-7,respectively,the corresponding starch concentration within simulated white water system was 200 mg/L.Whereas the enzymatically hydrolyzed starch exhibited a highest degradation ratio at a system temperature of 50℃and pH value of 5.5,respectively,and the corresponding starch concentration within simulated white water system was 100 mg/L.It was verified that native starch is more readily bio-hydrolyzed and biodegradation-susceptive by microorganisms in simulated white water system of OCC pulping process,while the enzymatically hydrolyzed starch exhibits better biodegradation/hydrolysis resistance to the microbial degradation than that of native starch.This study provides a practical and interesting approach to investigate the starch hydrolysis or biodegradation behaviors in white water system of OCC pulping process,which would greatly contribute to the full recycling and valorized application of starch as a versatile additive during paperboard production.

Enhanced initial biodegradation resistance of the biomedical Mg-Cu alloy by surface nanomodification

Mg-Cu alloys are promising antibacterial implant materials.However,their clinical applications have been impeded by their high initial biodegradation rate,which can be alleviated using nanotechnology by for example surface nanomodification to obtain a gradient nanostructured surface layer.The present work(i)produced a gradient nanostructured surface layer with a∼500µm thickness on a Mg-0.2 Cu alloy by a surface mechanical grinding treatment(SMGT),and(ii)studied the biodegradation behavior in Hank's solution.The initial biodegradation rate of the SMGTed samples was significantly lower than that of the unSMGTed original counterparts,which was attributed to the surface nanocrystallization,and the fragmentation and re-dissolution of Mg_(2)Cu particles in the surface of the SMGTed Mg-0.2 Cu alloy.Furthermore,the SMGTed Mg-0.2 Cu alloy had good antibacterial efficacy.This work creatively used SMGT technology to produce a high-performance Mg alloy implant material.

A Comparative Investigation of the Biodegradation Behaviour of Linseed Oil-Based Cross-Linked Composites Filled with Industrial Waste Materials in Two Different Soils

The biodegradation of polymeric biocomposites formed from epoxidized linseed oil and various types of fillers(pine needles,pine bark,grain mill waste,rapeseed cake)and a control sample without filler was studied during 180 days of exposure to two types of forest soil:deciduous and coniferous.The weight loss,morphological,and structural changes of polymer composites were noticed after 180 days of the soil burial test.The greatest weight loss of all tested samples was observed in coniferous forest soil(41.8%–63.2%),while in deciduous forest soil,it ranged between 37.7%and 42.3%.The most significant changes in the intensities of the signals evaluated by attenuated total reflectance infrared spectroscopy,as well as morphological changes determined by scanning electron microscopy,were assessed for polymer composite with rapeseed cake and specimen without filler in coniferous forest soil and are in a good agreement with weight loss results.Whereas significantly lower changes in weight loss,morphology,and structure of polymeric film with pine bark were noticed in both soils.It was suggested that fungi of Trichoderma,Penicillium,Talaromyces and Clonostachys genera are the possible soil microorganisms that degrade linseed oil-based cross-linked polymer composites.Moreover,the novel polymer composites have the potential to be an environmentally friendly alternative to petroleum-based mulching films.

Biodegradation of occluded hydrocarbons and kerogen macromolecules of the Permian Lucaogou shales,Junggar Basin,NW China

Three kerogen samples(JJZG-1,JJZG-2 and JJZG-3)isolated from the Permian Lucaogou shales of varying biodegradation levels(BLs≈0,3 and 7,respectively)were subjected to sequential stepwise pyrolysis combined with on-line detection of gas chromatography-mass spectrometry(GC-MS).Occluded fractions(bitumenⅡ)released at low-temperature steps(≥410℃)show consistent biodegradative signatures with that reported for solvent-extracted fractions(bitumenⅠ)of the original shales,e.g.,broad range of abundant n-alkanes,isoprenoids and regular hopanes for the non-biodegraded JJZG-1;trace n-alkanes and abundant hopanes for the moderately biodegraded JJZG-2;and no n-alkanes but still prominent hopanes including the microbially produced 25-nohopanes for the severely biodegraded JJZG-3.This consistency between bitumenⅡand bitumenⅠfractions indicates the biodegradability of the kerogenoccluded bitumenⅡwith limited protection from host kerogen.A minor level of protection was suggested by the trace distribution of n-alkanes in the bitumenⅡof JJZG-2,whereas the bitumenⅠhad no nalkanes.The kerogen itself was more resistant to biodegradation as reflected by the persistence of high abundances of both n-alkanes and hopanes in the high temperature(≥460℃)products of all three kerogen samples.However,the relative abundances of these product groups did show some evidence of biodegradation alteration,e.g.,ratios of n-C_(15)alkene/C_(27)hop-17(21)-ene at 510℃pyrolysis decreased by order of magnitude from the non-biodegraded(JJZG-1=27.4)to highly biodegraded(0.3 for JJZG-3)samples.The reduced biodegradation impact on the kerogen fraction(Cf.bitumen fractions)was also evident by the absence of 25-norhopanes in the high-temperature analysis of the JJZG-3 kerogen.

煤矿矿井水水质形成及演化的水动力场-水化学场-微生物场耦合作用与数值模拟

煤矿矿井水的水质形成与演化过程机理复杂,受水动力场、水化学场和微生物场等多场作用影响显著。深入研究并揭示煤矿矿井水水质形成机理与演化趋势、阐明采空区封闭后矿井水的多场耦合作用机制是矿井水污染防控与修复的理论基础。以鄂尔多斯盆地某煤矿采空区为水文地质原型,在前期研究的基础上,进一步建立了煤矿采空区积水水位回升、蓄满后水动力-水化学-微生物场(HCB)多场耦合室内相似模拟和数值模型。采空区水动力场研究结果表明基质-裂隙双孔隙模型能有效模拟采空区水位回升过程,模拟误差为9.9%,其模拟精度远高于理论预测和单孔隙模型。水化学场模拟结果与试验较为吻合,SO_(4)^(2-)、HCO_(3)-和p H模拟相对误差分别为3.0%、21.0%和6.2%,模拟结果较为可靠。模拟结果显示采空区蓄水过程中水岩反应和微生物作用不明显;而蓄满后水动力几乎停滞,但水化学场和微生物场较为活跃,2号煤和3号煤层中黄铁矿的氧化反应使得SO_(4)^(2-)质量浓度提升约24.6%;后期采空区水环境演化为弱酸性、厌氧还原条件,微生物降解作用凸显,将SO_(4)^(2-)有一定的“自净”能力。通过调整微生物代谢速率常数,可将SO_(4)^(2-)降解比例提高到61.6%。实际工程场景中可通过补充碳源、人工建立密闭厌氧环境等强化手段实现这一目标。将多场耦合室内试验和数值模拟技术拓展到煤矿采空区积水水质形成与演化规律研究,研究结论可为煤矿区矿井水污染防治提供指导。

MABR好氧喹啉和苯酚降解驱动反硝化脱氮研究

以喹啉和苯酚为含氮杂环类和酚类污染物为代表的废水是典型的强毒性难降解有机废水。该课题采用无泡膜曝气生物膜反应器(MABR)实现了好氧反硝化驱动喹啉和苯酚降解生物强化过程。反应器在不同工况条件下,完成了对喹啉、苯酚和硝酸盐分别为(82.6±10.2)%、(84.5±11.9)%、(67.3±10.6)%的去除率以及(11.1±1.4)、(3.1±1.2)、(1.91±0.4)g/(m^(2)·d)的去除负荷。胞外聚合物含量的增加有助于提高生物膜对高喹啉进水负荷的抵抗能力。通过解析生物膜菌群结构,发现生物膜能够有效富集Rhodococcus等典型好氧喹啉降解菌;通过q-PCR功能基因定量分析发现以oxoO为代表的喹啉降解基因和napA好氧反硝化指示基因存在同一菌群,说明了好氧反硝化驱动喹啉和苯酚降解菌群的存在。通过宏基因组学分析,进一步核定Pseudomonas和Raineyella是主要的好氧喹啉和苯酚降解协同反硝化功能的关键菌群。本课题证实了MABR生物膜在好氧条件下完成对喹啉和苯酚的高效降解和好氧反硝化耦合过程,为拓展MABR在含氮杂环和酚类有机废水处理的应用提供必要的理论参考。

拟康宁木霉对含铬黑T废水的处理特性研究

利用拟康宁木霉(Trichoderma koningiopsis)对铬黑T模拟废水进行脱色降解。以铬黑T去除率为指标,探究反应时间、初始铬黑T浓度、投菌量、葡萄糖用量、温度以及转速等对拟康宁木霉处理铬黑T效果的影响。通过正交实验探究拟康宁木霉处理铬黑T的最佳条件,并对其处理特性进行研究。结果表明:拟康宁木霉处理铬黑T模拟废水的最适条件包括初始铬黑T质量浓度20 mg/L,投菌量7.5 g/L,转速140 r/min,以0.4 g/L葡萄糖作为外加碳源,在30℃下反应20 h,铬黑T去除率达96.8%,且该菌对混合染料废水的去除率在90%左右。拟康宁木霉对铬黑T的吸附属于均质单层吸附,且符合一级动力学模型。拟康宁木霉对铬黑T的处理是通过生物吸附与降解的协同作用而实现。

瘤胃源粪臭素降解菌的分离鉴定及其降解特性研究

【目的】旨在从绵羊瘤胃中分离粪臭素降解菌,并评估其粪臭素降解能力和生长性能,以期开发适用于反刍动物降臭的直接饲喂微生物。【方法】以绵羊瘤胃液为分离来源,使用含有粪臭素的MSM培养基进行富集和分离,通过细菌菌落形态观察进行初步分类;应用16S rRNA基因扩增、测序及系统发育分析进行物种鉴定;绘制菌株生长曲线,通过HPLC技术测定粪臭素降解曲线。【结果】从绵羊瘤胃液中分离出25株粪臭素降解菌,经菌落形态鉴定选出11株代表菌株进行后续研究。物种鉴定结果显示,MSML2和MSML6属于枯草芽孢杆菌(Bacillus subtilis),MSML4、MSML5、MSML7和MSML10属于阿氏普里斯特氏菌(Priestia aryabhattai),MSML3和MSML11属于污染伯克霍尔德氏菌(Burkholderia contaminans),MSML1、MSML8和MSML9属于成都假单胞菌(Pseudomonas chengduensis)。其中,MSML5生长速度最快,在约12 h后进入稳定期,稳定期菌体浓度最高;MSML3和MSML8在前16 h生长缓慢,32 h后进入稳定期。在粪臭素降解方面,MSML2粪臭素降解效率最高,48 h内的降解率达到23.03%,其次是MSML7、MSML8和MSML10,降解率均超过20%。【结论】成功从绵羊瘤胃中分离获得25株粪臭素降解菌,涉及4个物种,首次报道了具备粪臭素降解能力的枯草芽孢杆菌、阿氏普里斯特氏菌和成都假单胞菌,为直接饲喂反刍动物的菌剂开发提供了宝贵的菌株资源。

垃圾渗滤液DOM在砂土中的迁移转化规律研究

目的针对焦作市城市生活垃圾卫生填埋场运行年限长(10 a以上)、防渗层趋于老化、渗滤液渗漏到地下水风险大的问题,方法以稀释5倍的老龄垃圾渗滤液为注入淋滤液,以填埋场粉砂土为岩土介质,在水力停留时间32 h下开展室内土柱模拟试验,分析老龄垃圾渗滤液中溶解性有机质(dissolved organic matter,DOM)的迁移转化规律。结果结果表明:0~2618 h内,溶解性有机碳(dissolved organic carbon,DOC),化学需氧量(chemical oxygen demand,COD)和波长254 nm单位比色皿光程下的紫外吸光度(UV254)在地下水中变化规律相似,且三者线性相关性显著,说明DOM组分以芳香族化合物为主;CXTFIT 2.1软件拟合得到DOC和COD的阻滞系数(3.01和1.96)及衰减系数均处于较低水平,说明砂土对有机质吸附作用有限;试验前期,淋出液的荧光指数(fluorescence index,FI)一直高于淋滤原液的,说明试验前期微生物生长快速;所有样品的FI均大于1.9,说明淋出液中DOM主要为生物源;垃圾渗滤液DOM含有较多富里酸(峰A、峰C)和腐殖酸类物质(峰E)及少量类蛋白物质(峰T2);淋出液S1中的微生物代谢产物(峰B)来源于试验所用砂土,S1中峰B和S2中峰T2随时间变化消失,剩下难降解的峰A、峰C和峰E,淋出液有机组分变化明显,结构简单的类蛋白物质逐渐消失,复杂难降解的腐殖类物质逐渐累积,试验过程中淋出液单位有机碳的总荧光峰强均高于淋滤液的,说明淋滤液在迁移转化过程中芳构化程度和腐殖化程度均有所提高。结论研究结果可为垃圾渗滤液处置与环境风险评估提供参考。

垄沟集雨覆盖种植对红豆草根系特征和产量的影响

【目的】为选择集雨垄的环境友好型覆盖材料,提高中国西北半干旱地区的降雨利用效率。【方法】通过随机区组大田试验,以传统平作为对照,研究3种材料(土壤结皮、生物可降解地膜和普通地膜)覆盖垄的垄沟集雨种植对土壤水热条件、红豆草根系特征、根瘤特征、干草产量和水分利用效率的影响。【结果】垄沟集雨种植显著改善土壤水热状况,增加红豆草根系和根瘤特征值。土壤结皮覆盖垄沟集雨种植显著提高红豆草水分利用效率,但降低红豆草干草产量;生物降解地膜和普通地膜覆盖垄沟集雨种植显著提高红豆草的干草产量和水分利用效率。与传统平作相比,土壤结皮、生物降解地膜和普通地膜覆盖垄沟集雨种植的土壤贮水量分别提高10.64、9.36和2.09 mm,垄上表层土壤温度分别增加2.0、3.4和4.2℃,红豆草根干重分别提高27%、72%和87%,有效根瘤数分别增加2.1、9.1和12.4个,水分利用效率分别提高11.9、23.3和30.0 kg/(hm^(2)·mm)。土壤结皮覆盖垄沟集雨种植的红豆草干草产量比传统平作降低13%,生物降解地膜和普通地膜覆盖垄沟集雨种植的红豆草干草产量比传统平作分别提高11%和23%。由于普通地膜残留极易导致土壤结构恶化和环境污染,不利于农业生产可持续性。【结论】在我国半干旱地区,生物可降解地膜覆盖垄沟集雨种植可作为一种高效、可持续的农业节水生产技术。

全生物降解地膜对湖南不同地区果蔬生长的影响

针对塑料地膜使用造成土壤环境污染的问题,研究以白色/黑色全生物降解地膜和普通塑料地膜为参试材料,在湖南省长沙市、沅江市、汉寿县等地区开展了西瓜、莴苣、秋葵等作物的覆膜试验,探究全生物降解地膜对不同作物的生长、品质、产量及土壤性质等指标的影响,观察全生物降解地膜的降解情况。结果发现,两种全生物降解地膜对湖南各地区果蔬生产均起到提质增效的作用。沅江地区黑色降解地膜覆盖栽培西瓜,西瓜单瓜重增加25.8%,叶片数增加45.5%,显著高于未覆膜处理;覆盖白色降解地膜的秋葵叶片长度比对照高42.1%,叶片宽度比对照高55.9%,叶片数增加43.2%,产量增加55.5%。普通塑料地膜在作物收获后未能降解,白色和黑色全生物降解地膜的降解率分别为80.3%~90.7%和63.0%~80.3%。综合不同地区的试验结果,认为两种降解地膜均可作为普通塑料地膜的潜在替代品,具有较大的推广前景。

含紫薯花青素的槟榔芋淀粉薄膜性能及其应用

开发含紫薯花青素(PSPA)并可生物降解的槟榔芋淀粉薄膜(TSF),并研究其光学性能、厚度、含水率、水溶性、颜色、总酚含量、抗氧化活性、红外光谱和微观结构等性能,初步探讨TSF对鲜切莴笋、鱼肉和猪肉储存过程中新鲜度的指示作用。研究表明TSF的紫外-可见光谱和PSPA溶液的光谱变化规律是一致的,表明PSPA与槟榔芋淀粉具有良好的成膜机制。TSF厚度适中,含水率为39.17%,水溶性为36.93%;TSF的DPPH清除率达到94%,表明TSF的抗氧化活性高。将TSF应用于鲜切莴笋、鱼肉和猪肉的新鲜度监测,TSF先呈现淡紫色,随着时间推移,鲜切莴笋、鱼肉和猪肉逐渐腐败变质,48 h后,TSF在莴笋中呈现蓝紫色、猪肉中呈现浅绿色、鱼肉中呈现淡黄色。

一种新型纤维素基包装材料的研制与应用设计

针对生物可降解包装材料的高成本、性能低等问题,制备一种以黄麻纤维、粘胶纤维和聚乳酸玉米纤维为主要原料的的纤维素基包装材料,并对其力学性能进行探究。结果表明,热压处理有利于增强纤维抱合性,从而增加材料的稳定性;黄麻/粘胶/玉米纤维最佳配比方案为50∶35∶15,此时,制备的复合包装材料的纵向断裂强力为212.35 N,横向断裂强力为126.78 N,纵向撕破强力为29.26 N,横向撕破强力为13.06 N,顶破强力为77.61 N。试验制备的黄麻/粘胶/玉米纤维素基包装材料不仅成本低、绿色环保,还具备较好的力学性能,能作为一种生物可降解包装材料应用于实际生活中。

紫外光固化接枝明胶改性可生物降解水性聚氨酯的性能研究

以聚己内酯二醇(PCL)为软段成分,丙烯酸羟乙基酯(HEA)为封端剂,制备了具有丙烯酸酯端基的水性聚氨酯(WPU)预聚体。将乙烯基三甲氧基硅烷(VTMS)与明胶水解缩合反应后得到的乙烯基接枝改性明胶(GH)通过共价键合的连接方式引入到WPU分子骨架中。通过紫外光固化将GH中的乙烯基和WPU预聚体中的丙烯酸酯末端连接,制备了可生物降解的WPU/GH复合材料。对WPU/GH的热性能、热失重性能及生物降解性能、降解后结晶度的变化等进行了测试和分析。结果表明,共价键合能提高WPU的成膜性能、耐水性和热稳定性。当GH含量达到10 wt.%时,WPU/GH在0.6%脂肪酶PBS溶液中的降解率达到68%,在土壤中的降解率达到56%。

可生物降解的食品活性包装技术进展现状

本研究界定了可生物降解的食品活性包装涵义,在此基础上阐明了可生物降解的活性包装在食品行业应用的必要性。考察和分析了各种可生物降解食品活性包装材料技术发展状况。指出可生物降解活性包装技术不是单一技术构成,而是由生物活性薄膜制备技术和活性物质释放动力学机制构成的技术体系。

聚乳酸纤维在纺织中的应用

聚乳酸来源于玉米、小麦、甜菜、木薯以及有机废弃物等原料,具有生物安全性、生物相容性、生物可降解性等特征。聚乳酸纤维的原料来源可再生,产品亲肤,废弃物可生物降解降解产物为二氧化碳和水。在实现“双碳目标”的今天,由聚乳酸制成的纤维在纺织物品中有广泛市场。通过介绍聚乳酸纤维几种加工方式,介绍聚乳酸纤维的优点,结合百姓生活中的应用案例分析,聚乳酸纤维与人们的生活息息相关,在纺织物品或其他领域中的应用比例将逐步增大,迎来一个重要的发展时期。

医用生物陶瓷的功能性生物适配机制及应用

为了获得满意的临床疗效,优质医用生物陶瓷应该具备怎样的性能一直困扰着广大研究者。自20世纪90年代以来,作者团队致力于研发医用生物陶瓷,从基础科学研究到成果转化,再到临床应用,积累了丰富的研究和应用经验,相继提出了“生物适配”和“精准生物适配”理论。本文围绕“医用生物陶瓷(磷酸钙类材料)的功能性生物适配”这一主题分享本团队的学术研究成果和临床应用经验,从结构适配、降解适配、力学适配、应用适配等四个角度,结合骨科临床应用背景,探讨如何实现其生物适配和设计制造的有效衔接,旨在为医用生物陶瓷的设计、制造、监管和应用提供依据和建议。

生物降解地膜对辣椒生长发育的影响

为明确不同材质生物可降解地膜对辣椒(Capsicum frutescens)生长发育的影响,选用聚乙烯地膜(PE)、天然产物类(PM1、PM2)、合成聚合物类降解膜[聚己二酸/对苯二甲酸丁二酯(PBAT)、聚羟基脂肪酸酯(PHA)等](PM3、PM4、PM5)进行田间试验,观察不同地膜的增温作用、降解性能和不同地膜覆盖下辣椒的生长性状。结果表明,辣椒生育前期(覆膜后0~52 d)是地膜增温的主要时期,覆膜种植主要提高该时期0~5 cm和5~10 cm土层各时间段土壤温度。其中,PM5的增温效果与PE相近,5~10 cm和10~15 cm土层土壤平均温度比CK(露地种植)提高了2℃以上。地膜覆盖使辣椒株高在覆膜后24~47 d得到明显生长,平均增长了20.28 cm,在覆膜后39 d,PM5比CK提高了8.2 cm;不同覆膜处理的辣椒叶绿素SPAD在覆膜后23 d存在显著差异,PM5和PE显著高于CK,分别提高了5.67和3.70。地膜覆盖对辣椒产量的影响表现为PM3、PM4、PM5处理的辣椒总产量均显著高于CK,分别提高了4 123、4 445、5 552 kg/hm^(2),其增产效果接近或优于PE,其中PM5对辣椒产量提升的效果最明显。因此,辣椒露天栽培推荐使用厚度为0.01 mm,主要成分为PBAT、PHA的可降解地膜。

Immobilization of microorganisms using carrageenan gels coated with chitosan and application to biodegradation of 4-chlorophenol

A new cell immobilization method based on the replacement of KCl by KCl+chitosan as the gelling agent was developed. The experimental results showed that through addition of chitosan into gelling agent, the mechanical strength and the thermal stability of the carrageenan gel were greatly improved. The new immobilization method was used to entrap a chlorophenol degrading microorganism. The immobilized microbial cells were applied for chlorophenol biodegradation. The experiments demonstrated that immobilized cells exhibit a higher bioactivity in the degradation of chlorophenol than free cells.

典型生物可降解塑料热处理特性及动力学

为了探究生物可降解塑料在热处理过程中的特性,采用热重分析仪分别在不同升温速率下(10,20和30℃/min)对由聚乳酸(PLA)和聚对苯二甲酸-己二酸丁二酯(PBAT)组成的生物可降解塑料(BP1)的失重特性进行分析,BP1在氮气和空气气氛下的反应过程都非一步完成,主要反应阶段都存在明显的两步失重过程,在氮气和空气气氛下两个主要反应阶段的质量损失率分别达到87.99%~89.64%,84.99%~86.88%,且两反应阶段温度区间存在明显重叠.利用Flynn–Wall–Qzawa(FWO)、Kissinger-Akahira-Sunose(KAS)、Starink三种等转化率法计算动力学参数,得到BP1在氮气气氛下阶段一、阶段二的平均活化能E分别是88.95,90.92kJ/mol,空气气氛下阶段一、阶段二的平均活化能E分别是67.23,91.27kJ/mol;采用积分主图分析法(Master-plots法)基于10℃/min确定其动力学反应机理,表明BP1主要反应阶段均符合随机成核和核生长模型(An),但反应级数有所区别,说明氮气和空气不同气氛,并不会影响其反应机理,只是在活性点位的产生和失活速率快慢方面有所区别.