Fermentation profile and microbial population in soybean silages with inoculant and powdered molasses

Fermentation profile and microbial population were assessed in soybean silages without any additive (control), with inoculant (I), with I + powdered molasses (I+M), and with powdered molasses only (M). Soybean plants were harvested at the R6 stage and ensiled in 2kg-capacity laboratory silos. The additives were added to the natural matter base of silages. The assessed fermentation periods were 1, 3, 7, 14, 28, and 56 days. A 4×6 factorial arrangement (4 additives × 6 fermentation periods) in a completely randomized design with 3 replicates was used. Lactic, acetic, and butyric acids concentrations were influenced by additives and periods (P< 0.05). It was observed higher lactic acid values to control silages, on the 56 th day. Lower average values of acetic and butyric acids were observed to I+M and M silages. It was observed quadratic effect to pH values with a reduction estimated of 0.5504, 0.5358, 0.6312 and 0.6680 units to pH values to control, I, I+M, and M silages in the first 10 days. A maximum lactic acid bacteria population was observed at the 28 th day of fermentation in silages with inoculant. The inoculant and powdered molasses improve the fermentation profile of soybean silages

Trypanocidal Activity Of Brazilian Plants Against Epimastigote Forms From Y And Bolivia Strains Of Trypanosoma Cruzi

Chagas disease is one of the main public health problems in Latin America. Since the available treatments for this disease are not effective in providing cure, the screening of potential antiprotozoal agents is essential, mainly of those obtained from natural sources. This study aimed to provide an evaluation of the trypanocidal activity of 92 ethanol extracts from species belonging to the families Annonaceae, Apiaceae, Cucurbitaceae, Lamiaceae, Lauraceae, Moraceae, Nyctaginaceae, and Verbenaceae against the Y and Bolivia strains of Trypanosoma cruzi. Additionally, cytotoxic activity on LLCMK2 fibroblasts was evaluated. Both the trypanocidal activity and cytotoxicity were evaluated using the MTT method, in the following concentrations: 500, 350, 250, and 100 μg/mL. Benznidazole was used for positive control. The best results among the 92 samples evaluated were obtained with ethanol extracts of Ocotea paranapiacabensis (Am93) and Aegiphila lhotzkiana (Am160). Am93 showed trypanocidal activity against epimastigote forms of the Bolivia strain and was moderately toxic to LLCMK2 cells, its Selectivity Index (SI) being 14.56, while Am160 showed moderate trypanocidal activity against the Bolivia strain and moderate toxicicity, its SI being equal to 1.15. The screening of Brazilian plants has indicated the potential effect of ethanol extracts obtained from Ocotea paranapiacabensis and Aegiphila lhotzkiana against Chagas disease.223528533Bastos, J.K., Albuquerque, S., Silva, M.L.A., Evaluation of the trypanocidal activity of lignans isolated from the leaves of Zanthoxylum naranjillo (1999) Planta Med, 65, pp. 1-4Batista Jr., J.M., Lopes, A.A., Ambrósio, D.L., Regasini, L.O., Kato, M.J., Bolzani, V.S., Cicarelli, R.M., Furlan, M., Natural chromenes and chromene derivatives as potencial antitrypanosomal agents (2008) Biol Pharm Bull, 31, pp. 538-540Botsaris, A., Plants used traditionally to treat malaria in Brazil: The archives of Flora Medicinal (2007) J Ethnobiol Ethnomed, 1, p. 18Buainain, A., Giazzi, J.F., Belda Neto, F.M., Martini, A.S., Rosa, J.A., Pozetti, G.L., Estudo da atividade de extratos vegetais sobre o desenvolvimento de Trypanosoma cruzi em meio líquido de Warren (1992) Rev Cien Farm, 14, pp. 93-102Cabral, M.M., Barbosa-Filho, J.M., Maia, G.L., Chaves, M.C., Braga, M.V., de Souza, W., Neolignans from plants in northeastern Brazil (Lauraceae) with activity against (2010) Trypanosoma Cruzi. Exp Parasitol, 124, pp. 319-324Costa-Lotufo, L.V., Silveira, E.R., Barros, M.C., Lima, M.A., de Moraes, M.E., de Moraes, M.O., Pessoa, C., Antiproliferative effects of abietane diterpenes from aegiphilla lhotzkyana (2004) Planta Med, 70, pp. 180-182Cotinguiba, F., Regasini, L.O., Bolzani, V.S., Debonsi, H.M., Passerini, D.O., Cicarelli, R.M.B., Kato, M.J., Furlan, M., Piperamides and their derivatives as potential antitrypanosomal agents (2009) Med Chem Res, 18, pp. 703-711Coura, J.R., Castro, S.L., A critical review on Chagas disease chemotherapy (2002) Mem I Oswaldo Cruz, 97, pp. 3-24Coura, J.R., Present situation and new strategies for Chagas disease chemotherapy: A proposal (2009) Mem I Oswaldo Cruz, 104, pp. 549-554Fernandes, O., Souto, R.P., Castro, J.A., Pereira, J.B., Fernandes, N.C., Junqueira, A.C., Naiff, R.D., Coura, J.R., Brazilian isolates of Trypanosoma cruzi from humans and triatomines classified into two lineages using mini-exon and ribosomal RNA sequences (1998) Am J Trop Med Hyg, 58, pp. 807-811Fournet, A., Ferreira, M.E., Rojas de Arias, A., Guy, I., Guinaudeau, H., Heinzen, H., Phytochemical and antiprotozoal activity of (2007) Ocotea Lancifolia. Fitoterapia, 78, pp. 382-384Lopes, A.A., López, S.N., Regasini, L.O., Batista, J.M., Ambrósio, D.L., Kato, M.J., da Silva, B.V., Furlan, M., In vitro activity of compounds isolated from Piper crassinervium against Trypanosoma cruzi (2008) Nat Prod Res, 22, pp. 1040-1046Macedo, A.M., Oliveira, R.P., Pena, S.D.J., Chagas disease: Role of parasite genetic variation in pathogenesis (2002) Exp Mol Med, 4, pp. 1-16Muelas-Serrano, S., Nogal-Ruiz, J.J., Gómez-Barrio, A., Setting of a colorimetric method to determine the viability of Trypanosoma cruzi epimastigotes (2000) Parasitol Res, 86, pp. 999-1002Nwaka, S., Ridley, R.G., Virtual drug discovery and development for neglected diseases through publicprivate partnerships (2003) Nat Rev Drug Discov, 2, pp. 919-928Osorio, E., Arango, G.J., Jiménez, N., Alzate, F., Ruiz, G., Gutiérrez, D., Paco, M.A., Robledo, S., Antiprotozoal and cytotoxic activities in vitro of Colombian Annonaceae (2007) J Ethnopharmacol, 111, pp. 630-635Regasini, L.O., Cotinguiba, F., Passerini, G.D., Bolzani, V.S., Cicarelli, R.M.B., Kato, M.J., Furlan, M., Trypanocidal activity of Piper arboreum and Piper tuberculatum (Piperaceae) (2009) Rev Bras Farmacog, 19, pp. 199-203Saraiva, J., Vega, C., Rolon, M., da Silva, R., Silva, M.L., Donate, P.M., Bastos, J.K., de Albuquerque, S., In vitro and in vivo activity of lignan lactones derivatives against Trypanosoma cruzi (2007) Parasitol Res, 100, pp. 791-795Tibayrenc, M., Ayala, F.J., The clonal theory of parasitic protozoa: 12 years on (2002) Trends Parasitol, 18, pp. 405-410(2010), http://www.who.int/mediacentre/factsheets/fs340/en/index.html, World Health Organization 2010, accessed in Au