RESUMEN
Carrot is an important root vegetable which plays an important role in human health. Globally, Post harvest diseases are the major constraint in carrot production, especially soft rot which resulting in severe yield loss. Early diagnosis of these post-harvest diseases paves a way for reducing the economic losses. Carrot samples showing typical rotting symptoms were collected from markets of four different districts of Tamil Nadu and the pathogen involved were isolated. Severe carrot soft rot incidence (66.74%) was observed in samples collected from Ooty area of The Nilgiris district and the least disease incidence of (16.21%) was recorded in Perundurai of Erode district. Pathogenicity of soft rot pathogen were conducted and the virulent isolates were identified based on Percent Disease Index (PDI) showing >50% rotting falls under disease grade 9 using disease grade scale (0 to 9). The bacterial isolates (KPB-7 and OCB-5) causing soft rot were characterized using various biochemical assays where in they showed positive response for methyl red, H2S gas production, KOH and catalase tests besides showing negative response for gram’s reaction. Furthermore, molecular characterization of 16s rRNA region revealed the soft rot isolate (KPB-7) as Pectobacterium carotovorum subsp carotovorum (with an accession number OR251119).
RESUMEN
The cocopeat production industry generates a significant amount of wastewater containing high organic loads and chemical residues, posing environmental challenges and economic concerns. This study aims to assess the potential of constructed wetlands as an innovative and sustainable approach for managing coco peat production industry wastewater. An artificial wetland was created and filled with 30% soil, 40% sand, 10% bio and hydrochar, and 20% gravel along with Canna indica was used as the plant component. Three types of hydraulic loading rates were studied: 5 ml/min, 10 ml/min, and 15 ml/min, with a retention time of 7 days.The results showed that the wastewater contains significant levels of Electrical Conductivity (5.24 – 6.31 dS m-1), Total Dissolved Solids (4190 - 5150 mg/L), Biochemical Oxygen Demand (730 - 818 mg/L), and Chemical Oxygen Demand (1825 – 2045 mg/L). The utilization of artificial wetlands along with Canna indica decreased the pollution loads by 42% of Electrical Conductivity, 41% of Biochemical Oxygen Demand, and Chemical Oxygen Demand, 45% of Total Suspended Solids, and 55% of Total Dissolved Solids.Based on the above results, constructed wetlands are recognized as a reliable wastewater treatment technique and a good solution for the treatment of coirpith washwater, which is a step towards a greener and more sustainable future. By integrating these natural filtration systems into the wastewater treatment process, industries can foster a harmonious coexistence with the environment, ensuring a balance between economic growth and environmental well-being.