RESUMEN
Chitosan has gained agro-industrial interest due to its potential applications in food preservation. In this work, chitosan applications for exotic fruit coating, using feijoa as a case of study, were evaluated. For this, we synthetized and characterized chitosan from shrimp shells and tested its performance. Chemical formulations for coating preparation using chitosan were proposed and tested. Mechanical properties, porosity, permeability, and fungal and bactericidal characteristics were used to verify the potential application of the film in the protection of fruits. The results indicated that synthetized chitosan has comparable properties to commercial chitosan (deacetylation degree > 82%), and, for the case of feijoa, the chitosan coating achieved significant reduction of microorganisms and fungal growth (0 UFC/mL for sample 3). Further, membrane permeability allowed oxygen exchange suitable for fruit freshness and natural physiological weight loss, thus delaying oxidative degradation and prolonging shelf-life. Chitosan's characteristic of a permeable film proved to be a promising alternative for the protection and extension of the freshness of post-harvest exotic fruits.
RESUMEN
RESUMEN En el mejoramiento del tomate (Solanum lycopersicum L.) se ha logrado un incremento significativo para el rendimiento y otras características productivas en un período corto de tiempo. Como consecuencia se redujo notablemente la diversidad genética. Si bien el germoplasma silvestre se ha utilizado principalmente como fuente de genes de resistencia para enfermedades y plagas, nuestro grupo inició en la década de 1990, un programa de mejoramiento genético en tomate para mejorar la calidad del fruto con especial énfasis en incrementar la vida poscosecha y también ampliar la variabilidad genética con la incorporación de estos genes al gran cultivo. Hemos desarrollado diferentes poblaciones a partir del cruzamiento interespecífico entre el cultivar argentino Caimanta de S. lycopersicum y la accesión LA0722 de S. pimpinellifolium L. Mediante la generación de cruzamientos entre estos padres selectos y el posterior avance generacional de la selección se ha tratado de dilucidar las bases genéticas que definen la calidad del fruto. Para ello se integraron al programa de mejoramiento información obtenida de datos genómicos, posgenómicos y bioinformáticos. Al mismo tiempo hemos desarrollado cuatro nuevos cultivares con características de calidad de fruto superiores al ser comparados con híbridos comerciales. Para conservar y estudiar la diversidad del cultivo también estamos desarrollado una colección de germoplasma que en la actualidad cuenta con 162 genotipos de tomate de diferentes especies y orígenes. Además, se ha iniciado la transferencia directa de plantines a huertas urbanas y periurbanas para favorecer el acceso a semillas de estos cultivares desarrollados en instituciones públicas.
ABSTRACT The genetic improvement of tomato (Solanum lycopersicum L.) has achieved an increase for yield and other agronomic traits in a short period of time. As a consequence, genetic diversity has been notably reduced. Wild germplasm has been mostly used as a source of resistance genes for diseases and pests. Our group started in the 1990' a breeding program in tomato for improving fruit quality, with special emphasis on increasing fruit shelf life and broadening the genetic variability with the incorporation of wild genes. We have developed different populations from the interspecific cross between the Argentine cultivar Caimanta of S. lycopersicum and the accession LA0722 of S. pimpinellifolium L. Through crosses between these selected parents and the subsequent generational selection advance, we attempted to elucidate the genetic bases that underlie tomato fruit quality. To do that, we use state-of-the-art technology available in the field of genetics and breeding programs, including genomic, post-genomic and bioinformatic data. At the same time, we have developed four new cultivars with improved fruit quality traits compared to commercial hybrids. To conserve and study the tomato diversity, we have developed a germplasm collection that currently contains 162 tomato genotypes from different species and origins. In addition, we have started a direct transfer of our cultivars to urban and peri-urban community orchards to facilitate them the access to genotypes that were developed in Argentine public institutions.
RESUMEN
This study aimed to understand the effect of silver nanoparticles (AgNPs) on physiochemical properties of hydroxypropyl methylcellulose (HPMC) film-forming solutions (FFS) and nanocomposite films (NCF), as well as the efficacy of these materials to control the development of anthracnose caused by Colletotrichum gloeosporioides in papaya (Carica papaya L.). FFS were characterized by pH, particle size distribution, and rheology. In addition, thickness, morphology, water contact angle, barrier, chemical, crystallinity, thermal, and mechanical properties from NCF were investigated. The minimum inhibitory concentration of AgNPs against C. gloeosporioides was determined by in vitro test. FFS with 0.25 wt% of AgNPs were used as coatings in papayas inoculated with C. gloeosporioides. Finally, the physicochemical parameters were investigated during their storing up to 7 days at 10 °C, followed by 7 days at 20 °C. The presence of AgNPs impacted the thickness, morphology, moisture content, chemical bonds, crystalline structure, and thermal properties of films. Coatings with 0.25 wt% of AgNPs reduced the incidence and severity of C. gloeosporioides and avoided the weight loss of papayas during storing. The ripening of papaya occurred naturally, showing that the coating only delayed this process. Thus, HPMC-AgNPs coating can be an alternative to extend the papaya shelf life.