ABSTRACT
A medida que a se avanza en el siglo XXI, los sistemas de energía deben alejarse de los combustibles fósiles y aumentar la capacidad de las energías renovables si se quieren cumplir los objetivos de temperaturas máximas del Acuerdo de París. Sin embargo, debido a los desafíos en la adopción de tecnologías bajas en carbono, ciertas áreas de los sistemas energéticos globales son difíciles de controlar y descarburar. Por otra parte, el compostaje es una de las prácticas de gestión de residuos orgánicos más importantes que se puede utilizar para lograr la sostenibilidad del suelo y del medio ambiente. El compost tiene un mínimo impacto en algunas emisiones, y puede ayudar a controlar la huella de carbono y limitar los efectos ambientales negativos de los métodos de eliminación de desechos más deficientes. La investigación tuvo por objetivo determinar la calidad de producir biogás y biometano a partir de la cáscara de plátano (Musa paradisiaca L.). Metodológicamente se desarrolló una investigación aplicada, con nivel de investigación de tipo experimental. Las cáscaras de plátano se colectaron de la planta de compostaje de la Municipalidad Provincial de Leoncio Prado, Perú. De la muestra se prepararon cinco sub muestras para la producción de biogás y cinco muestras adicionales para la producción de biometano. Los sistemas mostraron una producción de 0,067 m3 BG/Kg ST de biogás y 0,059 m3CH4/Kg ST de biometano, que generó subproductos como el biol y biosol. Estos resultados presentaron una baja toxicidad al ser sometidos a pruebas germinativas, concluyéndose que solo el 11,5% de la cáscara introducida al biorreactor se degrado y de esta fracción solo el 2,8% se convirtió en biogás(AU)
As progress is being made in the 21st century, energy systems must move away from fossil fuels and increase the capacity of renewable energies if you want to meet the maximum temperatures objectives of the Paris Agreement. However, due to the challenges in the adoption of low carbon technologies, certain areas of global energy systems are difficult to control and decarbure. On the other hand, composting is one of the most important organic waste management practices that can be used to achieve soil and environmental sustainability. The compost has a minimum impact on some emissions, and can help control the carbon footprint and limit the negative environmental effects of the most deficient waste removal methods. The research aimed to determine the quality of producing biogas and biomethane from the banana peel (Musa paradisiaca L.). Methodologically, an applied investigation was developed, with experimental research level. The banana peels were collected from the composting plant of the Provincial Municipality of Leoncio Prado, Peru. From the sample, five sub samples were prepared for the production of biogas and five additional samples for biomethane production. The systems showed a production of 0.067 m3 bg/kg ST of biogas and 0.059 m3ch4/kg ST of biomethane, which generated by -products such as biol and biosol. These results presented a low toxicity when they were subjected to germinative evidence, concluding that only 11.5% of the shell introduced into the bioreactor was degraded and of this fraction only 2.8% became biogas(AU)
Subject(s)
Conservation of Natural Resources/methods , Musa/metabolism , Biofuels/analysis , Carbon/analysis , Composting , Anaerobic Digestion , Musa/chemistry , Plant Bark/chemistry , Renewable EnergyABSTRACT
This study was carried out to evaluate by-product of the biodiesel industry as canola, safflower, forage turnip, and soybean crushed on the chemical composition, in situ degradability, and colonization time. Canola (Brassica napus L. var. oleifera), safflower (Carthamus tinctorius L.), forage turnip (Raphanus stivus L. var. oleiferus Metzg), and soybean (Glycine max) grains went through the oil extraction process by means of a cold pressing, resulting in the oilseeds-crushed. The treatments identification included: CAN Canola crushed; SAF Safflower crushed; TUR Forage turnip crushed; and SOY Soybean crushed. The oilseed-crushed treatments were quantified about mineral (calcium, magnesium, copper, iron, manganese, zinc, phosphorus and potassium), chemical composition (dry matter, ash, organic matter, crude protein, ether extract, neutral detergent fiber, acid detergent fiber, total carbohydrates, non-fibrous carbohydrates, and total digestible nutrient contents), In situ degradability, and colonization time. Magnesium, phosphorus, and zinc showed the greater values for TUR treatment 3.46, 27.4, 39.8, respectively, when compared to the other oilseed-crushed treatments. The TUR treatment had the lowest organic matter, whereas had the greater (p≤0.05; TUR and SOY treatments) for the non-fibrous carbohydrates. Ether extract was not affected (p>0.05) with the different oilseed-crushed treatments. Neutral detergent fiber was affected (p≤0.05) for CAN and SAF treatments with the greater values, 344 and 500 g/kg of dry matter, respectively. Soluble and potentially degradable fractions for SAF treatment showed similar results. Whereas the constant rate of degradation, presented the lowest value when compared to the other treatments. Effective degradability of crude protein was greater for CAN 63.2% than SOY 65.9% treatment, which had the lowest value. Potential degradability of crude protein did not differ between treatments. Colonization time for dry matter and crude protein were similar between TUR and SOY treatments. In conclusion, oilseeds-crushed from the biodiesel production can be targeted/used, as feed with great protein and energetic potential in the ruminant's production, considering the need of correct formulation and ingredients knowledge.
Subject(s)
Plant Oils/chemistry , Biofuels/analysis , Food AnalysisABSTRACT
The energetic values of crude glycerin (CG) were determined for broilers at different ages using the method proposed by Matterson and by polynomial regressions. Two trials were performed with broilers from 11 to 21 and from 31 to 41 days of age. The birds were distributed in a completely randomized experimental design with a reference ration (RR), without CG, and three ration tests with replacement of 5%, 10%, and 15% of RR by CG. The metabolizable energy values were calculated by the Matterson method, and the apparent metabolizable energy (AME) values were used in polynomial regression analysis. The mean values of AME, apparent corrected for nitrogen balance (AMEn), metabolizable coefficient of gross energy (CAMEB), and corrected for nitrogen balance (CAMEBn) of CG, for the phase from 11 to 21 days by the Matterson method were 10.08 MJ kg-1, 10.04 MJ kg-1, 67.06%, and 66.74%, respectively. The inclusion of CG presented an increasing linear effect for CAMEB and CAMEBn in this period. From 31 to 41 days, these values were 10.38 MJ kg-1, 10.27 MJ kg-1, 69.02%, and 62.24%, respectively. The predicted AMEn value through the polynomial regression equations was 10.49 MJ kg-1 and 10.18 MJ kg-1, respectively. According to the equations proposed by Matterson, the crude glycerin EMAn values for broilers from 11 to 21 and 31 to 41 days of age were 10.04 MJ kg-1 and 10.26 MJ kg-1, respectively. According to Adeola's method the AMEn values were 10.49 and 10.20 MJ kg-1 for each phase.(AU)
Os valores energéticos da glicerina bruta (GB) foram determinados para frangos de corte em diferentes idades, por meio da utilização do método proposto por Matterson e de regressões polinomiais. Foram realizados dois ensaios: de 11 a 21 dias e de 31 a 41 dias de idade das aves; em ambos, as aves foram distribuídas em um delineamento experimental inteiramente ao acaso, com uma ração referência (RR), sem GB, e três rações testes com substituição de 5%, 10% e 15% da RR por GB. Foram calculados os valores de energia metabolizável pelo método de Matterson, sendo os valores de energia metabolizável aparente (EMA) utilizados na análise de regressão polinomial. Os valores médios da EMA corrigida pelo balanço de nitrogênio (EMAn), o coeficiente de metabolizabilidade da EB (CMAEB) e o corrigido para o balanço de nitrogênio (CMAEBn) da GB, na matéria natural, para a fase de 11 a 21 dias, pelo método de Matterson, foram de 10,08 MJ kg-1, 10,04 MJ kg-1, 67,06% e 66,74%, respectivamente. A inclusão de GB apresentou um efeito linear crescente para os CMAEB e os CMAEBn. Na fase de 31 a 41 dias, foram de 10,38 MJ kg-1, 10,27 MJ kg-1, 69,02% e 62,24%, respectivamente. Por meio das equações de regressões polinomiais, o valor de EMAn estimada foi de 10,49 MJ kg-1 e 10,18 MJ kg-1, respectivamente. Os valores de EMAn da GB para as idades 11 a 21 e 31 a 41 dias foram de 10,04 MJ kg-1 e 10,26 MJ kg-1, respectivamente. De acordo com as equações propostas por Matterson e com o método de Adeola, os valores de EMAn foram 10,49 e 10,20 MJ kg-1 para cada fase.(AU)
Subject(s)
Animals , Chickens/metabolism , Biofuels/analysis , Glycerol/administration & dosage , Poultry/growth & developmentABSTRACT
Biodiesel production has been increasing yearly in Brazil. A large amount of glycerin is generated in this process and needs a correct destination. One possible use of this glycerin in crude form is in biotechnological processes. Xanthan gum is a commercial gum used primarily in the pharmaceutical and food industries as thickener, emulsifier and stabilizer. It is synthetized by species of the bacterium Xanthomonas generally from glucose. However, current research shows that species of this bacterium have the capacity to grow and synthesize the gum using glycerin from biodiesel. The aim of this study was to produce xanthan gum using glycerin from biodiesel production in medium with different nitrogen content, named complex and simple media. The kinetics of fermentation in simple medium showed a twofold increase in gum production (3.16 kg.m-3) compared to the one in complex medium (1.46 kg.m-3) after 120 hours. The gum generated in this study showed chemical and rheological characteristics of xanthan gum. Glucose supplementation did not show an increase in xanthan production but did increase the consistency index and the behavioral index of solutions of this gum.
Subject(s)
Biofuels/analysis , Biotechnology , Glycerol , Xanthomonas , GlucoseABSTRACT
The use of nonrenewable energy sources to provide the worldwide energy needs has caused different problems such as global warming, water pollution, and smog production. In this sense, lignocellulosic biomass has been postulated as a renewable energy source able to produce energy carriers that can cover this energy demand. Biogas and syngas are two energy vectors that have been suggested to generate heat and power through their use in cogeneration systems. Therefore, the aim of this review is to develop a comparison between these energy vectors considering their main features based on literature reports. In addition, a techno-economic and energy assessment of the heat and power generation using these vectors as energy sources is performed. If lignocellulosic biomass is used as raw material, biogas is more commonly used for cogeneration purposes than syngas. However, syngas from biomass gasification has a great potential to be employed as a chemical platform in the production of value-added products. Moreover, the investment costs to generate heat and power from lignocellulosic materials using the anaerobic digestion technology are higher than those using the gasification technology. As a conclusion, it was evidenced that upgraded biogas has a higher potential to produce heat and power than syngas. Nevertheless, the implementation of both energy vectors into the energy market is important to cover the increasing worldwide energy demand.
Subject(s)
Biofuels/analysis , Lignin/metabolism , Power Plants , Anaerobic Digestion , Biomass , Renewable Energy , Hot Temperature , Lignin/chemistry , MethaneABSTRACT
Abstract Glycerol from spent oil was processed by transesterification for biodiesel production. Although glycerol contains many types of impurities, it can be used as a C-source for lactic acid production by fungi, such as Rhizopus microsporus. In this study, we found that wild type R. microsporus (LTH23) produced more lactic acid than the mutant strains on cabbage glycerol media (CG media). More lactic acid was produced on CG media than on cabbage extract media (C media) by about two-fold in batch fermentation conditions. In addition, we found that lactic acid production in a fed-batch process was also slightly higher than in a batch process. To study the combined effects of pH, urea, and glycerol waste concentration on lactic acid production, a response surface methodology was used. The optimum pH, urea, and glycerol waste concentrations were pH 6.5, 3.75 g/L, and 17 g/L, respectively. The maximum lactic acid production predicted by this equation model was 4.03 g/L.
Subject(s)
Rhizopus/metabolism , Brassica/chemistry , Lactic Acid/metabolism , Glycerol/metabolism , Waste Products/analysis , Brassica/metabolism , Brassica/microbiology , Biotransformation , Cooking , Culture Media/metabolism , Culture Media/chemistry , Biofuels/analysis , Fermentation , Hydrogen-Ion ConcentrationABSTRACT
ABSTRACT Producing biofuels such as ethanol from non-food plant material has the potential to meet transportation fuel requirements in many African countries without impacting directly on food security. The current shortcomings in biomass processing are inefficient fermentation of plant sugars, such as xylose, especially at high temperatures, lack of fermenting microbes that are able to resist inhibitors associated with pre-treated plant material and lack of effective lignocellulolytic enzymes for complete hydrolysis of plant polysaccharides. Due to the presence of residual partially degraded lignocellulose in the gut, the dung of herbivores can be considered as a natural source of pre-treated lignocellulose. A total of 101 fungi were isolated (36 yeast and 65 mould isolates). Six yeast isolates produced ethanol during growth on xylose while three were able to grow at 42 °C. This is a desirable growth temperature as it is closer to that which is used during the cellulose hydrolysis process. From the yeast isolates, six isolates were able to tolerate 2 g/L acetic acid and one tolerated 2 g/L furfural in the growth media. These inhibitors are normally generated during the pre-treatment step. When grown on pre-treated thatch grass, Aspergillus species were dominant in secretion of endo-glucanase, xylanase and mannanase.
Subject(s)
Animals , Ethanol/metabolism , Fungi/isolation & purification , Fungi/metabolism , Manure/microbiology , Biofuels/analysis , Biofuels/microbiology , Fermentation , Fungi/classification , Fungi/genetics , Herbivory , Lignin/metabolism , Manure/analysis , Plants/metabolism , Xylose/metabolismABSTRACT
El objetivo del presente estudio fue hallar un modelo para estimar la incidencia de enfermedades tipo influenza (ETI), a partir de los términos de búsqueda relacionados recolectados por el Google Trends (GT). Los datos de vigilancia de ETI para los años 2012 y 2013 se obtuvieron del Sistema Nacional de Vigilancia de la Salud de Argentina. Las búsquedas de Internet se obtuvieron de la base de datos del GT, usando 6 términos: gripe, fiebre, tos, dolor de garganta, paracetamol e ibuprofeno. Se desarrolló un modelo de regresión de Poisson a partir de datos del año 2012, y se validó con datos del 2013 y resultados de la herramienta Google Flu Trends (GFT). La incidencia de ETI del sistema de vigilancia presentó fuertes correlaciones con las estimaciones de ETI del GT (r = 0,927) y del GFT (r = 0,943). Sin embargo, el GFT sobreestimó el pico de incidencia por casi el doble, mientras que el modelo basado en el GT subestimó el pico de incidencia por un factor de 0,7. Estos resultados demuestran la utilidad del GT como un complemento para la vigilancia de la influenza.
The aim of this study was to find a model to estimate the incidence of influenza-like illness (ILI) from the Google Trends (GT) related to influenza. ILI surveillance data from 2012 through 2013 were obtained from the National Health Surveillance System, Argentina. Internet search data were downloaded from the GT search engine database using 6 influenza-related queries: flu, fever, cough, sore throat, paracetamol, and ibuprofen. A Poisson regression model was developed to compare surveillance data and internet search trends for the year 2012. The model's results were validated using surveillance data for the year 2013 and results of the Google Flu Trends (GFT) tool. ILI incidence from the surveillance system showed strong correlations with ILI estimates from the GT model (r = 0.927) and from the GFT tool (r = 0.943). However, the GFT tool overestimates (by nearly twofold) the highest ILI incidence, while the GT model underestimates the highest incidence by a factor of 0.7. These results demonstrate the utility of GT to complement influenza surveillance.
O objetivo deste estudo foi encontrar um modelo para estimar a incidência da síndrome gripal com base nos termos de busca relacionados recolhidos pelo Google Trends (GT). Os dados de monitoramento de síndrome gripal entre 2012 e 2013 foram obtidos no Sistema Nacional de Vigilância de Saúde da Argentina. As pesquisas na Internet foram feitas baseando-se no banco de dados do GT usando 6 termos: gripe, febre, tosse, dor de garganta, paracetamol e ibuprofeno. Um modelo de regressão de Poisson foi desenvolvido valendo-se de dados de 2012. O modelo foi ajustado e validado com dados de 2013 e comparado com os resultados da ferramenta Google Flu Trends (GFT). A incidência de síndrome gripal mostrou uma forte correlação com estimativas do GT (r = 0,927) e GFT (r = 0,943). No entanto, o GFT superestimou o pico de incidência por quase o dobro, e o modelo baseado no GT subestimou o pico de incidência por um fator de 0,7. Esses resultados demonstram a utilidade do GT como um suplemento para a vigilância da influenza.
Subject(s)
Cities , Environmental Monitoring/statistics & numerical data , Environmental Pollutants/analysis , Siloxanes/analysis , Waste Products/analysis , Atmosphere/chemistry , Biofuels/analysis , Carbon/analysis , Fresh Water/chemistry , Molecular Structure , Siloxanes/chemistry , Soil/chemistryABSTRACT
Background: Bioethanol is produced mainly from sugar cane and corn. In the last years it has been subject of debate due to the effects in food prices and land use change. The use of lignocellulosic materials for bioethanol production, such as agroindustry, forestry and municipal residues, wood or dendroenergetic species, has been proposed as a sustainable way for producing this biofuel. The design of a sustainable process for producing bioethanol requires a methodological approach whereby economical, environmental and social criteria are systematically integrated from the early stages of process design. Results: Until now a methodology for guiding the design of a sustainable process for bioethanol production is not available, and there are just a few studies on this subject. Moreover, with the recent global concerns on climate change, developed technologies have been confronted with additional requirements to validate their sustainability. In this sense, the inclusion of sustainability criteria on process design becomes necessary for defining a systematic methodology to select the most appropriate operations in the process stages to achieve a sustainable bioethanol production. Conclusions: A description of the stages for the production of bioethanol from lignocellulosic materials is provided in this review and the main findings in relation to the more important sustainability indicators are presented.
Subject(s)
Ethanol/metabolism , Biofuels/analysis , Lignin/metabolism , Life Cycle StagesABSTRACT
The yeast Yarrowia lipolytica accumulates oils and is able to produce extracellular lipases when growing in different carbon sources including glycerol, the principal by-product of the biodiesel industry. In this study, biomass production of a novel mutant strain of Y. lipolytica was statistically optimized by Response Surface Methodology in media containing biodiesel-derived glycerol as main carbon source. This strain exhibited distinctive morphological and fatty acid profile characteristics, and showed an increased extracellular lipase activity. An organic source of nitrogen and the addition of 1.0 g/l olive oil were necessary for significant lipase production. Plackett-Burman and Central Composite Statistical Designs were employed for screening and optimization of fermentation in shaken flasks cultures, and the maximum values obtained were 16.1 g/l for biomass and 12.2 Units/ml for lipase, respectively. Optimized batch bioprocess was thereafter scaled in aerated bioreactors and the values reached for lipase specific activity after 95 % of the glycerol had been consumed, were three-fold higher than those obtained in shaken flasks cultures. A sustainable bioprocess to obtain biomass and extracellular lipase activity was attained by maximizing the use of the by-products of biodiesel industry.
Optimización de la producción de biomasa usando glicerol crudo, de una cepa mutante de Yarrowia lipolytica con actividad incrementada de lipasa. La levadura Yarrowia lipolytica acumula aceites y produce una lipasa extracelular al crecer en diferentes fuentes de carbono, entre ellas el glicerol, principal subproducto de la creciente industria del biodiésel. En el presente trabajo, se optimizó mediante la metodología de superficies de respuesta la producción de biomasa de una nueva cepa mutante de Y. lipolytica, empleando medios con glicerol derivado de la industria del biodiésel como principal fuente de carbono. Esta cepa presentó características morfológicas y perfil de ácidos grasos distintivos, y una mayor actividad de lipasa extracelular. Para obtener una producción significativa de lipasa extracelular, fue necesario el agregado de una fuente orgánica de nitrógeno y de 1 g/l de aceite de oliva. Se utilizaron los diseños estadísticos de Plackett-Burman y central compuesto para la selección y la optimización de las fermentaciones en frascos agitados; los máximos valores de biomasa y de lipasa obtenidos fueron de 16,1 g/l y 12,2 unidades/ml, respectivamente. Luego, el bioproceso en lote optimizado se escaló a biorreactores aireados, y los valores de actividad específica de lipasa alcanzados después de haberse consumido el 95 % del glicerol fueron tres veces más altos que los obtenidos en los cultivos en frascos agitados. En suma, se desarrolló un bioproceso sostenible para la obtención de biomasa y de una actividad de lipasa extracelular, que a la vez maximiza el uso de subproductos de la industria del biodiésel.
Subject(s)
Biomass , Culture Media/pharmacology , Fungal Proteins/genetics , Glycerol/pharmacology , Industrial Microbiology/methods , Lipase/genetics , Mycology/methods , Yarrowia/growth & development , Bioreactors , Biofuels/analysis , Culture Media, Conditioned/chemistry , DNA, Fungal/genetics , DNA, Intergenic/genetics , Fermentation , Fungal Proteins/biosynthesis , Genes, Fungal , Glycerol/isolation & purification , Hyphae/ultrastructure , Lipase/biosynthesis , Yarrowia/enzymology , Yarrowia/genetics , Yarrowia/ultrastructureABSTRACT
En este trabajo se ha estudiado las condicionesnecesarias para la producción de Biogas utilizando como fuente de carbono los Ácidos Grasos Volátiles, los cuales son obtenidos de la hidrólisis anaeróbica de la papa. Se han establecido Cultivos Batch metanogénicos y se ha determinado la influencia de los AGVs en la cinética de producción de Metano. De esta manera se observ que el Cultivo que tenía 11,68mg/ml de AGVs Totales tuvo una producción de 6,9% de Metano y 3,6% de Dióxido de Carbono, a los 45 días de haberse establecido el cultivo.Posteriormente, se estableci el cultivo continuo, en el cual la producción de biogás empez a los 11 días deestablecerse el cultivo, se obtuvo 1200 ml de Gas donde el 6,9% era Metano y 3,7% era Dióxido de carbono. La composición de gases fue medida con el detector portátil G3.16k LT 1522 LMSx.