Desodification from calcareous saline sodic soil through phytoremediation with Phragmites australis (Cav.) Trin. ex Steud. and gypsum.

The reclamation of saline sodic soils requires sodium removal and the phytoremediation is one of the proven low-cost, low-risk technologies for reclaiming such soils. However, the role of Phragmites australis in reclaiming saline sodic soils has not been evaluated extensively. The comparative reclaiming role of P. australis and gypsum was evaluated in a column experiment on a sandy clay saline sodic soil with ECe 74.7 dS m-1, sodium adsorption ratio (SAR) 63.2, Na+ 361 g kg-1, and pH 8.46. The gypsum at 100% soil requirement, planting common reed (P. australis) alone, P. australis + gypsum at 50% soil gypsum requirements, and leaching (control without plant and gypsum) were four treatments applied. After 11 weeks of incubation, the results showed that all treatments including the control significantly reduced pH, EC, exchangeable Na+, and SAR from the initial values, the control being with least results. The gypsum and P. australis + gypsum were highly effective in salinity (ECe) reduction, while sodicity (SAR) and Na+ reductions were significantly higher in P. australis + gypsum treatment. The reclamation efficiency in terms of Na+ (83.4%) and SAR (86.8%) reduction was the highest in P. australis + gypsum. It is concluded that phytoremediation is an effective tool to reclaim saline sodic soil.

Elemental Analysis of Medicinal Herb Fagonia indica Burm. f. and Its Rhizospheric Soil from Six Geographical Locations of South-eastern Sindh Province, Pakistan, During Spring and Summer Seasons.

This study hypothesized that seasons and geography may affect the elemental composition of Fagonia indica. The plant was sampled along with rhizospheric soil, from six hilly geographical sites of Sindh, during March (Spring) and July (Summer) and analyzed through ICP-OES. Among 20 elements detected, the elemental concentration of rhizospheric soil was significantly affected by geography rather than seasons. The rhizospheric soil elements, Fe, Mg, Hg, K, Mn, Na, Zn, Al, were hyper-concentrated, B, Ba, Cr, Cu, Pb, Sr were moderately concentrated, and As, Cd, Ni, Rb, Ti, V were concentrated in trace levels. Contrarily, elements in Fagonia indica biomass were significantly affected by both seasons and geography. K, Na, Fe, Hg, Al, Mn, Sr, Cr, Ti, V were hyperaccumulated during summer, while Mg, Zn, As, Ba, Cd, and Cu accumulated higher during spring. PCA reveals that elements with high variances were homogenously distributed to all sites except Rohri during spring, while during summer most elements were accumulated at Johi, Dadu, Jamshoro, and Karachi. In conclusion, the plant accumulates high concentration of heavy metals during summer and higher concentration of essential nutrients during spring; therefore, its collection for oral use can be recommended during spring.

Effect of Wall Material and Inlet Drying Temperature on Microencapsulation and Oxidative Stability of Pomegranate Seed Oil Using Spray Drying.

Pomegranate seed oil is a highly unsaturated fatty acid and liable to be oxidized; hence, oil was encapsulated to protect its bioactive materials and increase shelf life with the most common spray drying technique. Whey protein (WP) alone and in combination with Maltodextrin (MD) in the ratio 1:4 weight was utilized. Feed emulsion, droplet size, encapsulation efficiency (EE), moisture, bulk density, powder morphology, particle size, hygroscopicity, and solubility were also analyzed. The spray drying conditions were applied: inlet temperature 125 to 150°C and outlet 60 to 67°C, airflow rate 40-42 m3/mint, feed rate 5.2 g/m, and pump rate 40%. The shape of particles was spherical and round with dents on their surface. After encapsulation, the oxidative stability was monitored at 60°C for 15 days (8 h daily). The smaller droplet size of the emulsion was obtained at 35% total solid contents. WP alone showed better EE (90%) and oxidative stability than the combination of WP and MD as wall materials.