Worldly Portent of Face Uncovering and Women’s Dilapidation: A Comparative Study in Context With Quranic Injunctions

Assyrian Text is witnessed that women used veil for face covering with an additional piece of cloth about 13 centuries before the Christ. Then history of mankind displays veil in Egyptian society that was transparent and normally white in color. We found a handful evidences in Greek literature regarding veiling of face. History travels to Anglo-Saxon age and witnessed that women used veil to cover their hair of head. The head covering shows a biological reasoning also. Roman culture was the culture of fantasy, the veils were full of colorful, and multi designed veil arranged by flowers and different beautiful substantial. In Roman, veil developed from only head covering to shoulder covering and then from head to back covering. British regime also enrich the history of veil. There was beautiful designed, decorated with net clothes and covered with beautiful embroidery. The veil was empowered by elite community in England. Later it was popularized as a fashion in colonial communities. Through this thorough historic discussion, it is approved that veil used by women has a long history as the human history. In religious context, Hinduism is understood as the oldest religion on globe, it is found that in Harappan times about 2500 BC, Aryan women used to wear full body covering single cloth from head covering to foot, which was preached in Hindu religious book Vedas also, later the single cloth was known as Sari. And after the introduction of Christianity, Veil was introduced as a compulsory symbol of religion. Veil of whole body with strict rules can be seen in the form of Christian nun. Later, Islam explained veil of women in public as an obligatory sign. Islam is the youngest religion on earth, it was published rapidly and the implication of its rules are practiced prominently. After a thorough historic and religious discussion, it if proved in this article that veil was a compulsory part of human society and religions before Islam had also preached for veiling.  

Studies on Microbial and Plant Based Surfactants for Their Use in Soil Remediation

Natural surfactants are amphiphilic compounds derived from natural resources mainly plants and microorganism. Owing to their excellent physiochemical properties they are replacing synthetic surfactants in verity of commercial applications. In present study natural surfactants obtained from bacteria and two plants were studied for their possible role in rehabilitation of crude oil contaminated soils. In first phase of this study a biosurfactant producing bacterial strain was isolated from crude oil contaminated soil samples of Missa Kaswal oil field. Out of 51 bacterial strains only seven were found to be surfactant producing. The most efficient biosurfactant producing strains were including; M8, M9 and M10 based upon surface tension reduction, emulsification index, oil displacement and drop collapse test. The strain M9 showed highest reduction of surface tension of the culture medium i.e. 66.7 to 26.6 mN/m and 6.2 cm of oil displacement zone considered as the most efficient biosurfactant producing bacteria. The isolates M8, M9, and M10 identified by using morphological, biochemical and molecular techniques as different strains of Pseudomonas aeruginosa. Out of four different media, medium 4 proved to be the best in term of yielding highest amount of biosurfactants with all the three strains of Pseudomonas aeruginosa. Biosurfactant production was 2.31 g/L in medium 4, after 96 hrs by strain M9, whereas strain M8 and M10 produced relatively less biosurfactants. The strain M9 was the most efficient and selected for further studies. Optimization of different carbon sources revealed glycerol as the best in medium for the highest bacterial growth 1.37 g/L and biosurfactants production 2.890 g/L. The rhamnolipid production reached up to 4.44 g/L at optimum conditions i.e., pH 7, temperature 34 ˚C, agitation speed (rpm) 155, and 2.8 % inoculum. The media components were also optimized by using a combination of response surface and central composite design. The optimized medium composition pertaining to maximum rhamnolipids production of 5.67 g/L was obtained by using NaNO3 3.92 g/L, KH2PO4 2.3 g/L , MgSO4 0.26 g/L and FeSO4 0.0028 g/L. The chemical composition of biosurfactant produced by P. aeruginosa M9 was determined using HPTLC, FTIR and MALDI-Tof techniques. Results indicated that strain M9 produced a mixture of RL-1 and RL-2 during its growth on glycerol. The rhamnolipid produced by P. aeruginosa M9 were studies under effect of varying pH, salt concentration and temperatures. Results suggested that rhamnolipids retained their activity between pH 4-10, 1-21 % NaCl and 121 ˚C. In addition, 0.2 % of the crude rhamnolipid was sufficient to decrease the surface tension of the waster to 26.6 mN/m. The n-butanolic extract of S. mukorossi and A. concinna were analyzed for the presence of saponins using TLC and FTIR spectroscopy. The results indicated presence of saponins in both the plants. Results indicated that saponins from S. mukorossi and A. concinna were stable at pH 4-9, 25-121 ˚C, and 1-21 % NaCl. The crude saponin extracted from S. mukorossi reduced the surface tension of the water to 39.1 mN/m at a concentration of 0.2 % (w/v). On the other hand, surface tension Acacia saponin reduced the surface tension to 42.0 nM/m. The role of natural surfactants obtained from microbial and plants resources were studied in surfactant enhanced soil remediation by using Taguchi’s Orthogonal Array Design. Removal of crude oil from the soil collected from Missa Keswal oil field was determined under the effect of different temperatures, shaking speed, surfactant concentration and time. Results indicated 94 % reduction in crude oil from the soil at 55°C, 200 rpm, 1% rhamnolipid concentration after 15 hrs. In case of Sapindus saponins, maximum removal was 87 % at optimum conditions of; 65 °C, 200 rpm, 0.8 % saponins and 15 hrs of process time. The results of soil washing using Acacia saponins revealed that 65°C, 200 rpm, 0.8 % saponin and 15 hours were the optimum soil washing conditions pertaining to a maximum removal of 78 % crude oil from the soil. The soil obtained from GCU garden was washed at optimized condition obtained for each natural surfactant. Maximum removal of 81 % was carried out by Sapindus saponins, followed by 78 % by rhamnolipids and 67 % using Acacia saponins. These findings suggested that natural surfactants have excellent potential to be used in soil remediation of complex hydrocarbons such as crude oil.