RESUMO
Improper use of water resources in irrigation that contain a significant amount of salts, faulty agronomic practices such as improper fertilization, climate change etc. are gradually increasing soil salinity of arable lands across the globe. It is one of the major abiotic factors that inhibits overall plant growth through ionic imbalance, osmotic stress, oxidative stress, and reduced nutrient uptake. Plants have evolved with several adaptation strategies at morphological and molecular levels to withstand salinity stress. Among various approaches, harnessing the crop genetic variability across different genepools and developing salinity tolerant crop plants offer the most sustainable way of salt stress mitigation. Some important major genetic determinants controlling salinity tolerance have been uncovered using classical genetic approaches. However, its complex inheritance pattern makes breeding for salinity tolerance challenging. Subsequently, advances in sequence based breeding approaches and functional genomics have greatly assisted in underpinning novel genetic variants controlling salinity tolerance in plants at the whole genome level. This current review aims to shed light on physiological, biochemical, and molecular responses under salt stress, defense mechanisms of plants, underlying genetics of salt tolerance through bi-parental QTL mapping and Genome Wide Association Studies, and implication of Genomic Selection to breed salt tolerant lines.
RESUMO
Objectives: Transdermal drug delivery as a novel drug delivery system has become a major research interest to the scientists for its controlled drug release and improved patient compliance. This study was conducted to develop an optimized transdermal patch of tramadol hydrochloride using an appropriate amount of suitable polymers. It was also planned to control the drug permeation rate from the device to achieve a sustained release pattern. Materials and Methods: Several numbers of formulations were prepared by altering the amount of excipients. Physicochemical and biopharmaceutical parameters were checked to get the optimized formulation with desired characteristics. Results: Fourier transform infrared spectroscopy results displayed no abnormal peaks and hence concluded that the drug and polymers were compatible with each other. The minimum standard deviation values of different physicochemical parameters assured that the method of preparation was skilled to develop patches with least intra-batch variability. A higher percentage of hydroxypropyl methylcellulose (HPMC) resulted in the greater tensile strength, moisture content and water vapor transmission rate of the patches. A high folding endurance value (>200) indicated the flexibility of the prepared patches and their integrity to the skin. The transdermal patches coded as F26 containing only HPMC polymer demonstrated the desired drug permeation rate (65.51%) within 12 hours through ex vivo permeation studies. Conclusion: The formulation coded as F26 was found to be the most optimized patch as it exhibited sustained drug permeation rate followed by higuchi diffusion kinetics, that also confirmed the capability of the formulation to exhibit matrix type drug delivery.
