5 research outputs found
Microorganisms associated to tomato seedlings growing in saline culture act as osmoprotectant
Full text linkLignina obtenida de residuos agr铆colas como biocombutible de tercera generaci贸n.
Get PDFEl bioetanol lignocelul贸sico es uno de los biocarburantes de segunda generaci贸n m谩s estudiado en la actualidad. Su producci贸n requiere la eliminaci贸n total o parcial de la lignina presente en el material vegetal. Esta lignina puede ser aprovechada para la generaci贸n de energ铆a t茅rmica y el茅ctrica, ayudando a disminuir los costos que implica el abastecimiento energ茅tico a partir de biomasa. Lo anterior resulta importante para Baja California, M茅xico, dada las grandes cantidades de material lignocelul贸sico generado en sus cultivos agr铆colas. En 2013, se generaron 527,103 t de paja de trigo y 98,004 t de vara de algod贸n. Para el desarrollo de esta investigaci贸n se aisl贸 y cuantific贸 el contenido de lignina Klason en dichos residuos (ASTM D1106). Despu茅s, se determin贸 el poder calor铆fico superior (PCS) (ASTM E711) y se realiz贸 el an谩lisis pr贸ximo (ASTM E870). Finalmente, se evalu贸 el potencial energ茅tico de ambas ligninas como biocombustible de la regi贸n. Como resultados, se encontr贸 que en 2013, se dispon铆an de 92,519 t de lignina de paja de trigo y 18,135 t de lignina de vara de algod贸n, cuyos PCS fueron 22.99 MJ/kg y 24.99 MJ/kg, respectivamente. El potencial energ茅tico fue 2,573 TJ, equivalente a la energ铆a obtenida de 78,951 t de carb贸n antracita 贸 102,953 t de carb贸n lignito. Seg煤n el an谩lisis pr贸ximo esta lignina puede ser usada en procesos eficientes de conversi贸n, como gasificaci贸n o co-combusti贸n con carbones sub-bituminosos; convirti茅ndola en un importante recurso energ茅tico de tercera generaci贸n para la regi贸n
In Vitro Assessment of Early Bacterial Activity on Micro/Nanostructured Ti6Al4V Surfaces
No full textIt is imperative to understand and systematically compare the initial interactions between bacteria genre and surface properties. Thus, we fabricated a flat, anodized with 80 nm TiO2 nanotubes (NTs), and a rough Ti6Al4V surface. The materials were characterized using field-emission scanning electron microscopy (FE-SEM), energy dispersive X-ray spectroscopy (EDX) and atomic force microscopy (AFM). We cultured in vitro Staphylococcus epidermidis (S. epidermidis) and Pseudomonas aeruginosa (P. aeruginosa) to evaluate the bacterial-surface behavior by FE-SEM and viability calculation. In addition, the initial effects of human osteoblasts were tested on the materials. Gram-negative bacteria showed promoted adherence and viability over the flat and rough surface, while NTs displayed opposite activity with altered morphology. Gram-positive bacteria illustrated similar cellular architecture over the surfaces but with promoted surface adhesion bonds on the flat alloy. Rough surfaces supported S. epidermidis viability, whilst NTs exhibited lower vitality. NTs advocated promoted better osteoblast organization with enhanced vitality. Gram-positive bacteria suggested preferred adhesion capability over flat and carbon-rich surfaces. Gram-negative bacteria were strongly disturbed by NTs but largely stimulated by flat and rough materials. Our work proposed that the chemical profile of the material surface and the bacterial cell wall characteristics might play an important role in the bacteria-surface interactions
