Biotechnological processes for conversion of corn into ethanol

Ethanol has been utilized as a fuel source in the United States since the turn of the century. However, it has repeatedly faced significant commercial viability obstacles relative to petroleum. Renewed interest exists in ethanol as a fuel source today owing to its positive impact on rural America, the environment and United States energy security. Today, most fuel ethanol is produced by either the dry grind or the wet mill process. Current technologies allow for 2.5 gallons (wet mill process) to 2.8 gallons (dry grind process) of ethanol (1 gallon = 3.785 l) per bushel of corn. Valuable co-products, distillers dried grains with solubles (dry grind) and corn gluten meal and feed (wet mill), are also generated in the production of ethanol. While current supplies are generated from both processes, the majority of the growth in the industry is from dry grind plant construction in rural communities across the corn belt. While fuel ethanol production is an energy-efficient process today, additional research is occurring to improve its long-term economic viability. Three of the most significant areas of research are in the production of hybrids with a higher starch content or a higher extractable starch content, in the conversion of the corn kernel fiber fraction to ethanol, and in the identification and development of new and higher-value co-products.     

Biotechnological solubilization of rock phosphate on media containing agro-industrial wastes

Rock phosphate (RP) is an important natural material traditionally used for the production of phosphorus (P) fertilizers. Compared with chemical treatment, microbial solubilization of RP is an alternative environmentally mild approach. An overview of biotechnological techniques, mainly based on solubilization processes involving agro-industrial residues, is presented. Potential advantages of composting, solid-state fermentation, and liquid submerged fermentation employing free and immobilized microorganisms that produce organic acids and simultaneously solubilize RP are discussed. Subsequent introduction of the final fermented products into soil-plant systems promotes plant growth and P acquisition.     

Biodeuteration of poly(beta-hydroxybutyrate).

The formation of poly(beta-hydroxybutyrate), PHB, by Rhodobacter sphaeroides and Alcaligenes eutrophus was studied using the following carbon sources and solvents: (1), acetate in H2O; (2), D3-acetate in H2O; (3), acetate in 90 to 92% D2O; and (4), D3-acetate in 90 to 92% D2O. The growth of Rb. sphaeroides cultured under condition (2) showed no apparent deuterium isotope effect, while considerably slowed growth in the presence of D2O was observed under conditions (3) and (4). In all cases, the PHB produced under deuterium enriched conditions was of high molecular weight. Interestingly, comparatively high volumetric formation of partially deuterated PHB was obtained using culture condition (4) for A. eutrophus. Fourier transform infrared spectroscopy (FT-i.r.), pyrolysis gas chromatography mass spectrometry (PGC-m.s.), and nuclear magnetic resonance (n.m.r.) were used to establish the extent and distribution of deuterium in the PHB samples produced. Partially deuterated PHB was obtained in each case, using a deuterium enriched culture. Considerable differences in the extent and distribution of deuterium were found between micro-organisms and culture conditions.     

Development of anaerobic filters for treatment of high strength agro-industrial wastewaters

The suitability and advantages of anaerobic filters for the treatment of various agro-industrial wastewaters are discussed. Recent developments in reactor design and typical operating parameters and performance data are given for reactors operated in the up- and downflow mode. The distribution of the most important process parameters throughout the reactor height is discussed and methods for process optimization are presented.     

新型生物可降解塑料——多聚羟基烷酸研究进展

面对日益严重的白色污染 ,人们迫切需要一种能在自然界较快分解的新型塑料。多聚羟基烷酸是原核生物在不平衡代谢条件下形成的碳源和能源贮藏物质 ,这种贮藏物质如同淀粉、糖原一样 ,当生命活动需要时可以再分解利用。由于多聚羟基烷酸有着与石化塑料相似的理化性质 ,又能在一定条件下被微生物迅速而彻底地降解 ,因此是一种理想的传统石化塑料替代品。1　多聚羟基烷酸的理化及生物学特性1 1　多聚羟基烷酸的分子结构及理化性质多聚羟基烷酸是由羟基脂肪酸单体首尾相联构成的高分图 1　多聚羟基烷酸的分子结构子聚合物。又分为不同种类。如多…     

Plant-based material, protein and biodegradable plastic

Fibrous proteins from spiders, proteins with synthetic multiple repeats and mammalian structural proteins such as collagen have been produced in transgenic plants. Recent advances in the production of biodegradable plastic in plants also show the potential of molecular farming for research into and production of materials. Selection of a growing variety of such products, optimization of expression, and the development of effective purification strategies will further promote this growing field of biotechnology.     

Anaerobic treatability and biogas production potential studies of different agro-industrial wastewaters in Turkey

The anaerobic treatability and methane generation potential of the wastewaters of the three important agro-industries in Turkey, namely, cheese-making, poultry breeding and the olive-oil mill industries were studied. Biochemical methane potential (BMP) experiments were conducted for different initial chemical oxygen demand (COD) concentrations. The results indicate that anaerobic treatment was possible for all the wastewaters studied and the biogas produced had a high methane content.     

Properties of a bacterium which degrades solid poly(tetramethylene succinate)-co-adipate, a biodegradable plastic

Various microorganisms were screened for their ability to degrade poly(tetramethylene succinate)-co-(tetramethylene adipate) (PBSA). Strain BS-3, which was newly isolated from a soil sample, was selected as the best strain. From taxonomical studies, the strain was tentatively ascribed to belong to the genus Acidovorax, most probably to the species A. delafieldii. Strain BS-3 could degrade both solid and emulsified PBSA, and also emulsified poly(tetramethylene succinate). During the degradation, a lipase activity was observed in the culture broth. This lipase activity was induced more strongly by PBSA than by tributyrin or triolein which are typical substrates of lipase. These observations strongly suggest that this lipase was involved in the PBSA biodegradation in strain BS-3.     

Biotechnological conversion of waste cooking olive oil into lipid-rich biomass using Aspergillus and Penicillium strains

Aims: In this study, we have investigated the biochemical behaviour of Aspergillus sp. (five strains) and Penicillium expansum (one strain) fungi cultivated on waste cooking olive oil. The production of lipid‐rich biomass was the main target of the work. In parallel, the biosynthesis of other extracellular metabolites (organic acids) and enzyme (lipase) and the substrate fatty acid specificity of the strains were studied. Methods and Results: Carbon‐limited cultures were performed on waste oil, added in the growth medium at 15 g l^?1, and high biomass quantities were produced (up to c. 18 g l^?1, conversion yield of c. 1·0 g of dry biomass formed per g of fat consumed or higher). Cellular lipids were accumulated in notable quantities in almost all cultures. Aspergillus sp. ATHUM 3482 accumulated lipid up to 64·0% (w/w) in dry fungal mass. In parallel, extracellular lipase activity was quantified, and it was revealed to be strain and fermentation time dependent, with a maximum quantity of 645 U ml^?1 being obtained by Aspergillus niger NRRL 363. Storage lipid content significantly decreased at the stationary growth phase. Some differences in the fatty acid composition of both cellular and residual lipids when compared with the initial substrate fat used were observed; in various cases, cellular lipids more saturated and enriched with arachidic acid were produced. Aspergillus strains produced oxalic acid up to 5·0 g l^?1. Conclusions: Aspergillus and Penicillium strains are able to convert waste cooking olive oil into high‐added‐value products. Significance and Impact of the Study: Increasing fatty wastes amounts are annually produced. The current study provided an alternative way of biovalourization of these materials, by using them as substrates, to produce added‐value compounds.     

Integrated production of biodegradable plastic, sugar and ethanol

Poly 3-hydroxybutyric acid (PHB) and related copolymers can be advantageously produced when integrated into a sugarcane mill. In this favorable scenario, the energy necessary for the production process is provided by biomass. Carbon dioxide emissions to the environment are photosynthetically assimilated by the sugarcane crop and wastes are recycled to the cane fields. The polymer can be produced at low cost considering the availability of a low-price carbon source and energy.     

Supercritical fluid disruption of Ralstonia eutropha for poly(beta-hydroxybutyrate) recovery

A new method for disruption of Gram-negative bacterium Ralstonia eutropha by supercritical CO(2) for poly(beta-hydroxybutyrate) (PHB) recovery is proposed. The effects of different parameters such as exposure time, pressure, temperature, volume of methanol as a modifier, and culture history on cell disruption efficiency were investigated using Taguchi's statistical approach to determine optimum conditions. The optimum conditions for cell disruption and PHB recovery were as follows: exposure time, 100 min; pressure, 200 atm; temperature, 40 degrees C; volume of methanol, 0.2 mL. The cell culture time was less significant. At optimum conditions, the maximum efficiency of PHB recovery was found to be 89%. The proposed method is comparable with other recovery methods in terms of the percentage of PHB recovery, while it is environmentally more benign.     

生物降解地膜应用与地膜残留污染防控

地膜是农业生产中重要的生产资料之一,过去30多年,地膜用量和农作物覆膜面积一直稳定增长,2014年地膜用量达到了144万t,覆膜面积超过1 800万hm~2,该技术对保障我国农产品安全供给作出了重大贡献。与此同时,地膜残留污染问题越来越严重,一些农田的地膜残留量超过250 kg/hm~2,在我国西北的局部区域,地膜残留已经对农田土壤、作物生长发育、农事作业等造成严重影响和危害。生物降解地膜成为替代普通PE地膜、解决地膜残留污染的一种有效措施和手段,目前生物降解地膜正处于产品研发和评价试验的关键阶段,部分生物降解地膜产品在马铃薯、花生、烟草生产上显示出良好的效果,但总体上还面临巨大挑战,主要包括需要进一步提高地膜产品质量,提高地膜产品破裂和降解可控性,改善地膜的增温保墒能力,实现满足农作物对地膜覆盖功能的要求;此外,需要降低生物降解地膜综合成本,促进生物降解地膜规模化应用。总体上,随着技术进步和农业生产环境的变化,生物降解地膜应用将具有良好的前景。     

Production,optimization and characterization of polyhydroxybutyrate,a biodegradable plastic by Bacillus spp.

Poly-β-hydroxybutyrate (PHB) is the intracellular lipid reserve accumulated by many bacteria. The most potent terrestrial bacterium Bacillus cereus SE-1 showed more PHB accumulating cells (22.1 and 40% after 48 and 72 h) than that of the marine Bacillus sp. CS-605 (5 and 33% after 48 and 72 h). Both the isolates harbored phbB gene and the characteristics C=O peak was observed in the extracted PHB by Fourier transformed infrared spectroscopy analysis. Maltose was found to be the most suitable carbon source for the accumulation of PHB in B. cereus SE-1. The extracted PHB sample from B. cereus SE-1 was blended with a thermoplastic starch (TS) and an increased thermoplasticity and decreased crystallinity were observed after blending in comparison to the standard PHB. The melting temperature (T_m), melting enthalpy (?Hf), and crystallinity (X_c) of the blended PHB sample were found to be 109.4 °C, 64.58 J/g, and 44.23%, respectively.     

Contact angle, WAXS, and SAXS analysis of poly(beta-hydroxybutyrate) and poly(ethylene glycol) block copolymers obtained via Azotobacter vinelandii UWD

This study investigated and correlated physical properties and cell interactions of copolymers obtained by a poly(ethylene glycol) (PEG)-modulated fermentation of Azotobacter vinelandii UWD. PEGs with molecular weights of 400 and 3400 Da and di(ethylene glycol) (DEG) were used to modulate the bacterial synthesis of poly(beta-hydroxybutyrate) (PHB). The PHB crystallinity was determined by wide-angle X-ray scattering (WAXS). Small-angle X-ray scattering (SAXS) showed that lamellar distances decreased between the PHB and the PHB modulated with PEG or DEG. Furthermore, the contact angle of water on the PHB/PEG polymer surfaces decreased when compared to that of PHB. The significant decrease of the contact angle and corresponding increase in surface tension, as well as significant decrease in cell adhesion, suggest the presence of hydrophilic PEG and DEG within the hydrophobic surface.     

Biotechnological upcycling of plastic waste and other non-conventional feedstocks in a circular economy

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Starch-based extruded plastic films and evaluation of their biodegradable properties

Plastic formulations containing up to 40% starch were prepared and blown into thin films using extrusion methods. Extruded films were evaluated for their biodegradability by exposing them to a consortium of starch degrading bacteria in the laboratory for 45 days and in the La Silla river located in Monterrey, N.L. Mexico for up to 60 days. Biodegradability was assessed by measuring changes in weight loss and chemical composition of the films using Fourier transform infrared (FTIR) spectroscopy. While little or no degradation was apparent in control films made up of 100% low density polyethylene (LDPE) or 100% poly-(ethylene-co-acrylic acid) (EAA), most of the starch was depleted in starch-containing films exposed in the river. Starch degradation in films exposed to amylolytic bacteria in the laboratory was relatively slower. Also, increasing the amount of EAA from 25% to 50% substantially reduced starch depletion in these films.Abbreviations FTIR Fourier transform infrared - LDPE low density poly-(ethylene) - EAA poly-(ethyleneco-acrylic acid) - SEM Scanning electron microscopy The mention of firms names or trade products does not imply that they are endorsed or recommended by the U. S. Department of Agriculture over the firms or similar products not mentioned. All programs and services of the U. S. Department of Agriculture are offered on a nondiscriminatory basis without regard to race, color, national origin, religion, sex, marital status, or handicap.     

Starch-based extruded plastic films and evaluation of their biodegradable properties

Plastic formulations containing up to 40% starch were prepared and blown into thin films using extrusion methods. Extruded films were evaluated for their biodegradability by exposing them to a consortium of starch degrading bacteria in the laboratory for 45 days and in the ‘La Silla’ river located in Monterrey, N.L. Mexico for up to 60 days. Biodegradability was assessed by measuring changes in weight loss and chemical composition of the films using Fourier transform infrared (FTIR) spectroscopy. While little or no degradation was apparent in control films made up of 100% low density polyethylene (LDPE) or 100% poly-(ethylene-co-acrylic acid) (EAA), most of the starch was depleted in starch-containing films exposed in the river. Starch degradation in films exposed to amylolytic bacteria in the laboratory was relatively slower. Also, increasing the amount of EAA from 25% to 50% substantially reduced starch depletion in these films.     

Production of 9-hydroxynonanoic Acid from methyl oleate and conversion into lactone monomers for the synthesis of biodegradable polylactones

The feasibility of a previously established method based on ozonolysis and hydrogenation reactions for the production of 9-hydroxynonanoic acid from oleic acid has been demonstrated. Metal catalyzed lactonization conditions have been used to convert 9-hydroxynonanoic acid into 1,11-dioxacycloicosane-2,12-dione, which is a potential monomer in the synthesis of polylactones. The structure of 9-hydroxynonanoic acid and 1,11-dioxacycloicosane-2,12-dione has been confirmed by 1H NMR, 13C NMR, and FTIR. In addition, 9-hydroxynonanoic acid was analyzed by high-resolution mass spectroscopy and 1,11-dioxacycloicosane-2,12-dione was analyzed by GC-MS. Aliphatic poly(nonanolactones) have been synthesized via ring-opening polymerization of the dilactone. The structure and number average molecular weight (M(n)) of the poly(nonanolactones) have been calculated by 1H NMR and GPC. The physical properties of these poly(nonanolactones) have been characterized by modulated differential scanning calorimetry (MDSC) and thermogravimetric analysis (TGA).