Application of microcrystalline cellulose obtained from Gossypium herbaceum in direct compression of chlorpheniramine maleate tablets

The flow, tableting and in vitro release properties of directly compressed chlorpheniramine maleate (CPM) tablets containing fluid bed dried and lyophilized microcrystalline cellulose (MCC) obtained from Gossypium herbaceum (GH) were investigated. Delignification of dried GH linters was done through the soda process to obtain alpha cellulose which was hydrolyzed with 2.0 N hydrochloric acid to get MCC. The MCC was washed with water until neutral. Drying was done by either fluid bed method or lyophilization to obtain MCC-GossF and MCC-GossL respectively. Chlorpheniramine tablets containing 20, 30 and 40% of the MCCs were prepared by direct compression method. Avicel PH102 (AVH-102) served as comparing standard. Using standard methods, evaluation of the powders and the tablets was done. The evaluated parameters of the powders and tablets conformed to the British Pharmacopoeia specifications. The CPM tablets containing MCC-GossF (coded CGF) had better flow but were not mechanically as strong as those containing MCC-GossL (coded CGL). The hardness and disintegration times of the tablets were in the order of CGF < CGL and the friability was in the order of CGF > CGL. Similar parameters of DCL compared well with CPM tablets containing AVH-102 (coded DAV). The MCC obtained from GH had dilution potential up to 40% except in CGF-4 tablets. The in vitro dissolution showed > 80% CPM release from all the batches within 30 min. The release kinetics were of mixed order while the mechanism of drug release was Fickian. The MCCs served as good directly compressible binder for chlorpheniramine maleate.

The use of un-composted spent mushroom residue as a replacement of peat in substrates for Gossypium herbaceum and Talinum paniculatum

In order to evaluate the effect of growing media with peat and spent mushroom residue (SMR) on medicinal plants, we cultured Gossypium herbaceum and Talinum paniculatum seedlings in the substrates with SMR in proportions of 0% (control), 25%, 50%, 75%, and 100%. Results showed that G. herbaceum seedlings can survive in all treatments, but T. paniculatum seedlings died out in 75% and 100% SMR substrates where higher electrical conductance was found (2.3-2.7 dS m-1). Both growth and biomass mostly declined with the increase of SMR proportion in the growing media for the two species except for root biomass in T. paniculatum seedlings between the control and the 25% SMR treatment. Shoot nitrogen (N) and phosphorus (P) concentrations and contents tended to be higher in low- and high-SMR-proportional substrates, respectively. N and P statuses were both diagnosed to be excessive than needed for the two species. Overall, it was not recommended to culture G. herbaceum seedlings in the substrates with SMR; instead T. paniculatum seedlings can be cultured in the growing media with SMR in volumetric proportion of 25%.

Morphological description of a novel synthetic allotetraploid(A1A1G3G3) of Gossypium herbaceum L.and G.nelsonii Fryx. suitable for disease-resistant breeding applications

Wild species of Gossypium ssp. are an important source of traits for improving commercial cotton cultivars. Previous reports show that Gossypium herbaceum L. and Gossypium nelsonii Fryx. have better disease resistance characteristics than commercial cotton varieties. However, chromosome ploidy and biological isolation make it difficult to hybridize diploid species with the tetraploid Gossypium hirsutum L. We developed a new allotetraploid cotton genotype (A1A1G3G3) using a process of distant hybridization within wild cotton species to create new germplasms. First of all, G. herbaceum and G. nelsonii were used for interspecific hybridization to obtain F1 generation. Afterwards, apical meristems of the F1 diploid cotton plants were treated with colchicine to induce chromosome doubling. The new interspecific F1 hybrid and S1 cotton plants originated from chromosome duplication, were tested via morphological and molecular markers and confirmed their tetraploidy through flowrometric and cytological identification. The S1 tetraploid cotton plants was crossed with a TM-1 line and fertile hybrid offspring were obtained. These S2 offsprings were tested for resistance to Verticillium wilt and demonstrated adequate tolerance to this fungi. The results shows that the new S1 cotton line could be used as parental material for hybridization with G. hirsutum to produce pathogen-resistant cotton hybrids. This new S1 allotetraploid genotype will contributes to the enrichment of Gossypium germplasm resources and is expected to be valuable in polyploidy evolutionary studies.