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1.
Braz J Biol ; 84: e284877, 2024.
Article in English | MEDLINE | ID: mdl-39319930

ABSTRACT

The soil is a dynamic environment, influenced by abiotic and biotic factors, which can result in changes in plant development. This study aimed to assess the impact on vegetative growth of chia (Salvia hispanica L) inoculated with Trichoderma harzianum and on the rhizosphere microbiome. The experimentation was conducted in a greenhouse under controlled conditions growing chia plants in pots containing soil with a clayey texture. Different concentrations of T. harzianum (0; 2.5; 5.0; 10.0; 20.0 µL. g-1 of seed) were applied to the chia seeds before planting. Morphological parameters, including plant height (cm), number of branches, stem diameter (mm), number of days to flowering and shoot and root dry masses (g) were quantitatively assessed. After the cultivation period, soil samples from the rhizosphere region were collected for subsequent chemical and metagenomic analyses. These samples were also compared with the control soil, collected before installing the experiment. The results showed that increasing doses of T. harzianum promoted a significant increase in the diameter of the stem, number of branches, dry biomass of the root system and the number of days to flowering, without modifying the overall height of the plants. Soil metagenomics indicated that T. harzianum inoculation modified the microbial diversity of the rhizosphere environment, with more pronounced effects observed in samples treated with higher concentrations of the inoculant. Furthermore, there were changes in the chemical composition and enzymes related to soil quality in correlation with the concentrations of the applied inoculant. This study demonstrated that inoculating chia seeds with T. harzianum not only promotes specific morphogenetic characteristics of the plant, but it also has a significant impact on the microbial diversity and biochemical functionality of the soil, including an observed increase in the populations of T. harzianum and T. asperellum.


Subject(s)
Metagenomics , Salvia , Soil Microbiology , Salvia/microbiology , Rhizosphere , Biomass , Hypocreales/physiology , Plant Roots/microbiology
2.
Rev. bras. plantas med ; Rev. bras. plantas med;16(2,supl.1): 337-344, 2014. graf, tab
Article in Portuguese | LILACS | ID: lil-719462

ABSTRACT

O uso de plantas medicinais e seus derivados para o tratamento de doenças é uma prática antiga e se percebe, atualmente, uma crescente procura por produtos naturais, incluindo medicamentos, produtos alimentícios, e cosméticos. Hortelã pimenta (Mentha x Piperita L), além de ser uma planta medicinal, pode ser utilizada para obtenção de aromatizantes, infusões, e temperos. O processo de secagem se faz necessário para aumentar o tempo de conservação e a vida útil do produto facilitando seu transporte, manuseio, e armazenamento. Para que os produtos derivados da hortelã pimenta tenham qualidade é necessário estudos sobre o processo de pré e de pós-colheita. Objetivou-se neste estudo identificar a temperatura de secagem, em duas velocidades de ar circulante, que minimize a degradação da cor das folhas e permita obter maior rendimento de óleo essencial. Folhas da hortelã foram colhidas manualmente no horário entre 7:15 e 8:00, e submetidas a secagem em duas velocidades do ar (0,3 e 0,5 m.s-1) e em cinco temperaturas (30, 40, 50, 60 e 70 °C). O material seco foi analisado quanto à cor utilizando-se colorímetro com escala do sistema CIELab baseado em coloração dentro dos padrões da Norma DIN 6174 (1979). A quantificação do óleo essencial foi realizada por hidrodestilação em aparelho Clevenger. Observou-se que temperaturas superiores a 50 °C reduzem o rendimento. A cor das folhas submetidas à secagem diferencia-se da cor das folhas frescas. De acordo com a Norma DIN 6174, a cor das folhas submetidas a secagem com temperatura até 40 °C são "Facilmente distinguíveis" e para as folhas submetidas à secagem a temperaturas superior a 50 °C, a diferenciação é "Muito grande". Conclui-se que para obter o máximo de rendimento do óleo essencial e o mínimo de degradação da cor, a secagem deve ser realizada a temperatura de até 50 ºC. A velocidade do ar de secagem, na faixa de 0,3 a 0,5 m.s-1, não afetou os parâmetros avaliados.


The use of medicinal plants and their derivatives for the treatment of diseases is an ancient practice. Currently, there is a growing demand for natural products, not only medicines, but also food and cosmetics. The peppermint (Mentha x piperita L.), in addition to being a medicinal plant, can be used for obtaining flavorings, spices and tea infusions. The drying process is necessary to increase the shelf life of the product and to facilitatg itr transport, handling and storage. For peppermint derivatives of sufficient quality, it is necessary studies on the pre- and post-harvest. The objective of this study is to identify the temperature and air velocity that minimizs the degradation of the color of the leaves with higher oil yield. PepperMint leaves were harvested manually from 7:15 to 8:00 a.m. and dried in trays in a completely randomized design in a 2 x 5 factorial design, being two air velocities (0.3 and 0.5 m.s-1) and five temperatures (30, 40, 50, 60 and 70 °C) with three replications. The dried material was analyzed for color using a colorimeter with the CIELab scale system based on a color within the DIN 6174 standards (1979). The quantification of the essential oil was performed by hydrodistillation in a Clevenger-type apparatus. The analyzes were performed in triplicate. Ws observed that the yield of essential oil of the dry leaves was highertwhan compared to the yield presented by the fresh leaves. This effect was attributed to the fact that the lower water content in the leaves enables the vapor stream generated in the extractor to promots a more effective drag of the volatile oilcompounds stored in the cells; however, a temperature exceeding 50 °C promotes a reduction in yield. The color of the leaves submitted to drying is different from the color of fresh leaves. According to the DIN 6174 standard, the color of the leaves subjected to drying at the temperature up to 40 °C is "easily distinguishable" and, for the leaves submitted to drying at temperatures higher than 50 °C, the differentiation is "too large". We conclude that to get the maximum yield of essential oil and minimal color degradation, drying should be carried out at a temperature of up to 50 °C. The rate of the drying processes in the rangeofrom 0.3 to 0.5 m.s-1 did not affect the parameters evaluated.


Subject(s)
Mentha piperita/metabolism , Fixed Bed , Plants, Medicinal/classification , Analysis of Variance , Color , Plant Leaves/genetics
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