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Engenharia

封装固体材料的细菌纤维素球体

Published: February 26, 2021
doi:
10.3791/62286
, , , , ,
1Department of Environmental Engineering,Montana Technological University, 2Department of Petroleum Engineering,Montana Technological University, 3Department of Metallurgical & Materials Engineering,Montana Technological University, 4Department of Mechanical Engineering,Montana Technological University

Summary

该协议提供了一种简单、廉价的方法,可以形成细菌纤维素(BC)球体。这种生物材料可以作为固体材料的封装介质,包括生物炭、聚合物球体和矿废物。

Abstract

自BC作为一种新材料的普及以来,细菌纤维素(BC)球体的研究日益增多。该协议为 BC 球体生产提供了一种经济实惠且简单的方法。除了产生这些球体外,还确定了固体粒子的封装方法。生产BC球体,水,红茶,糖,醋和细菌培养物结合在一个困惑的烧瓶和内容是搅拌。在确定BC球体形成的适当培养条件后,使用生物炭、聚合物珠和矿废物测试了它们封装固体粒子的能力。球体的特点是使用图像J软件和热重度分析(TGA)。 结果表明,直径为7.5毫米的球体可在7天内制成。添加各种颗粒会增加 BC 胶囊的平均大小范围。球体封装了10-20%的干质量。此方法显示了低成本的球体生产和封装,这些生产和封装是很容易获得的材料所可能实现的。BC 球体将来可能用作污染物清除辅助工具、受控释放肥料涂层或土壤修正。

Introduction

细菌纤维素(BC)因其机械强度、高纯度和晶体、保水能力和复杂的纤维结构1、2、3、4而备受业界关注。这些特点使不列颠哥伦比亚省成为各种应用的有利生物材料,包括生物医学、食品加工和环境修复使用1。形成BC薄膜可以与单一的有机体文化或混合文化,如那些用于康布查5,发酵茶饮料。酿造康布查依赖于”细菌和酵母的共生文化”,俗称SCOBY。利用这种生物共生培养,采用类似的技术来创造BC球体。这种生物材料可用于帮助分离环境污染物和锚定农业修正,如生物炭,以实现更高效的作物生产。

以前的文献已经讨论了BC在激动的条件下产生的特点与BC在静止文化中产生的特点。静止培养物在液空气接口形成薄膜,而摇动培养物导致液体6中悬浮的不同 BC 粒子、链和球体。许多研究都提到BC的商业生产在动态条件下更可行的说法,为应用本文的方法提供了依据。此外,还对BC球体的结构和性质进行了各种调查。丰田章男等人6比较困惑和光滑的墙埃伦迈尔烧瓶在他们的激动BC生产。Hu 和 Catchmark4的一项研究确定了 BC 球体的确定条件,这些球体被用作当前 BC 球体生产过程的指南,其结果表明,球体大小在 60 小时后不会继续增加。穆罕默德等人对不列颠哥伦比亚省生产的回顾表明,动摇不列颠哥伦比亚省的文化甚至确保了氧气的供应和分配,这是不列颠哥伦比亚省成功增长所必需的。荷兰等8国利用X射线衍射和富利埃变异红外光谱法研究了不列颠哥伦比亚省的晶体和化学结构。据推测,BC胶囊将表现出类似的特征,未来的研究将研究结构特性。研究还探讨了利用BC生产改进的生物复合物的有益效果。研究人员以环氧树脂为基础,表明BC的加入可改善疲劳寿命、断裂韧性、拉伸和弯曲强度物质特征。正如过去和目前的研究所表明的,许多人对不列颠哥伦比亚省的商业化使用感兴趣。

许多研究人员已经研究了受控释放系统中的细菌纤维素,这里描述的方法产生胶囊,可以用作受控释放系统。这项研究主要集中在生物医学领域的控制释放,以及控制释放肥料(CRF)管理方面的一些探索。根据不列颠哥伦比亚省控制释放阿莫西林11号、利多卡因12号和布洛芬13号的成功,BC可能表现出与其他物质类似的输送特征,如颗粒化肥料。沙维夫和米克尔森14日对CRF的概述承认,CRF的CRF比传统的施肥效率更高,节省劳动力,而且通常比常规肥料施用更不会造成环境退化。细菌纤维素可以作为CRF的有利封装材料。肥料可能会从不列颠哥伦比亚省的膜中渗出,或作为BC生物降解15,16排放。BC的高水膨胀能力也可以作为一个有益的土壤修正17,18,19,因为肥料养分和水分都可以通过应用BC球体释放到地面。有了这些特性,BC球体封装形成的CRF可能比其他在生产和处置阶段可能产生负面影响的肥料涂层材料具有优势。将 BC 调整为肥料涂层可能会进一步改进 CRF 技术。通过降低肥料释放率,作物将有足够的时间来吸收肥料,防止过量径流进入水体,从而减少富营养化和非氧体区。类似的缓释肥料已经准备和试验使用聚合物涂层20。

与先前研究中概述的协议不同,本协议侧重于均匀、有凝聚力的球体生产,而不是高纤维素产量。此外,BC封装其他固体已被研究与纤维素薄膜,但不是球体21。通过扩大对细菌纤维素球体的研究,可以采取进一步措施,以商业生产BC,这是有益的,因为BC的环境安全的特点。这种BC球体制造方法采用廉价、现成的烹饪成分。初始组装后,BC 球体在 2 天内开始形成,不受干扰。通过这种策略生产 BC 球体需要的空间很小,并且有一个可食用的副产品,发酵茶”康布查”。其他研究中提到的封装技术包括通过相反转技术22、23、矩阵形成24、喷干燥25形成的涂层,以及合成26期间的直接封装。本手稿中概述的直接封装方法对那些希望使用现成材料的简单、廉价过程的人来说是有用的。

通过这项研究,创建了一个成功的BC球体生产和封装协议。BC球体可以在其单独结构中封装生物炭、矿尾矿和聚苯乙烯微珠的固体颗粒。BC 虽然尚未在工业领域广泛使用,但它是一种实用、可持续制造的自然产生的材料,可用于未来的应用。

Protocol

1. 细菌纤维素起动培养物的创造和维护 以SCOBY的形式获得细菌纤维素的起始培养,约50克。它可以以商业性(例如,从健康文化中购买)。将 SCOBY 放入 1 升烧嘴中,上面覆盖着纸巾。 煮沸700mL的除离子水,将其从含有SCOBY的容器转移到单独的容器中,并加入85克蔗糖。 蔗糖溶解后,加入2袋红茶(4.87克)。将茶浸泡1小时,然后用搅拌棒小心取出茶包。 在茶中加入200升…

Representative Results

BC球体在前48小时文化中增长最快(图2)。图2还显示了球体如何倾向于达到最大平均大小,然后保持恒定。在这个实验中,球体的平均直径达到7.5±0.2毫米。虽然BC球体在10天的生长期内从未完全恶化,但它们确实开始形成肌腱,在第八天左右从球体的主体延伸开来。这可以在图2E中看到,最明显的是在左上部的大球体上。 <p cla…

Discussion

本协议概述了 BC 球体的生产和封装方法,这些方法易于操作且具有成本效益。通过对原始协议的各种调整,确定了一个适当的程序。必须采取关键步骤,以确保有生存能力的领域。BC 形成中涉及的所有成分在球体的健康和耐用性中起着关键作用。蔗糖为生物提供饲料,茶提供氮气,醋将pH到最佳条件,以防止不必要的污染物28。此方法的另一个重要变量是温度。茶必须冷却到室?…

Declarações

The authors have nothing to disclose.

Acknowledgements

这项工作是蒙大拿州技术研究助理导师项目由阿道夫·马丁内斯,凯瑟琳·穆赫兰,泰勒·萨默维尔和劳雷尔·比特曼的延续。研究由国家科学基金会根据第1号赠款赞助。OIA-1757351和作战能力发展指挥部陆军研究实验室(合作协议编号W911NF-15-2-0020)。本材料中表达的任何意见、发现和结论或建议均为作者的意见、发现和结论,并不一定反映国家科学基金会或陆军研究实验室的观点。我们还要感谢艾米·昆齐、李·理查兹、凯特琳·艾利、克里斯·加蒙斯、马克斯·沃尔根南特和克里斯·博世的贡献。

Materials

100 mL graduated cylinder
1000 mL beaker
25 mL graduated cylinder
250 mL Erlenmeyer baffled flask Chemglass CLS-2040-02
500 mL beaker
Balance
Biochar Ponderosa pine heat treated under argon gas, heated at 15 °C per minute to 800 °C
Black tea
Deionized water
Distilled white vinegar
Elastic band
Microbial starter culture Cultures for Health
Mine waste Collected from Butte, MT: 46.001978,-112.582465. Mine waste contains soil and metals originating from past copper mining. Mn, Si, Ca, Al, and Fe were the five most prevalent elements measured in the mine waste through x-ray diffraction.
Mortar and pestle
Orbital shaker Used various brands
Paper towel
Polystyrene microbeads Polybead 17138 3 micron diameter
Stir rod
Sucrose
Tea kettle
TGA TA Instruments TA Q500 400 °C/min to 800 °C, 100 mL/min N2
Thermometer
XRF Analyzer ThermoFisher Scientific 10131166
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Referências

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Tags

Keywords: Bacterial CelluloseCellulose SpheresBiomaterialBiodegradableEncapsulationSolid MaterialsTeaVinegarSugarMicrobial Starter CultureOrbital ShakerBaffle Flask
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Bitterman, L. A., Martinez, A., Mulholland, C., Somerville, T., Prieto-Centurion, D., Zodrow, K. R. Bacterial Cellulose Spheres that Encapsulate Solid Materials. J. Vis. Exp. (168), e62286, doi:10.3791/62286 (2021).
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