Compacted Area with Effective Links (CAEL) for Data Dissemination in VANETs.

Vehicular ad hoc network (VANET) is a specialized form of wireless network that is solely intended for collaboration between vehicles. Several studies have shown that standard routing protocols cannot be implemented in VANETs because of their unique characteristics such as their significant count of vehicles on the network and the rapid evolution of the network's design. Because VANET communication links are broken very frequently, it is necessary to address the routing consistency of these highly dynamic networks. The transmission of VANET data may result in a substantial amount of overhead in the routing process; thus, it is vital to address the issue of overhead to enhance the overall network performance. The proposed protocol named compacted area with effective links (CAEL) is designed to focus on decreasing overhead to achieve an enhancement in PDR performance inside the network. The communication between selected nodes that have been judged to be dependable in terms of geographical location and appropriate existing links between vehicles is focused on achieving this goal. With the inclusion of the reliability factor, it is possible to complete the important step of removing extraneous nodes, with the selection of the trustworthy nodes being made based on the link expiration time during the whole routing procedure. When compared to our previously published protocols, i.e., Dynamic Trilateral Enrollment (DyTE) and Reliable Group of Vehicles (RGoV), the results of the simulations demonstrate that CAEL has achieved an overall improvement in the performance of the network.

In vitro antioxidant, hepatoprotective potential and chemical profiling of Syzygium aromaticum using HPLC and GC-MS.

The objective of the present study was to evaluate the in vitro antioxidant and hepatoprotective potential of Syzygium aromaticum (clove) against CCl4-induced hepatotoxicity using rat liver slice culture (LSC) model. Antioxidant activity in terms of DPPH radical scavenging activity and ferric reducing antioxidant power (FRAP) of different concentrations of S. aromaticum was in the range of 41.01-90.33% and 138.15-595.63 Fe (II) mg/mL, respectively. Plasmid pBR322 DNA protection activity was observed with all three concentrations of S. aromaticum against H2O2 induced oxidative damage, as no strand breaks were observed. Chemical profiling through HPLC confirmed the presence of six major phenolic acids and 13 volatile bioactive compounds were identified though GC-MS. Significant hepatoprotection (p<0.05) was observed in liver slice culture (LSC) as liver slices treated with various concentrations of S. aromaticum extract presented very low percentage cytotoxicity (7.35-16.16%) as compared to the CCl4 treated liver slices (75.58 %). The hepatoprotective potential of S. aromaticum may be due to the presence of bioactive components as confirmed by HPLC and GC-MS. The results of present study support the use of S. aromaticum in the formation of potential hepatoprotective drugs against various liver diseases.

Cardioprotective and Metabolomic Profiling of Selected Medicinal Plants against Oxidative Stress.

In this research work, the antioxidant and metabolomic profiling of seven selected medicinally important herbs including Rauvolfia serpentina, Terminalia arjuna, Coriandrum sativum, Elettaria cardamom, Piper nigrum, Allium sativum, and Crataegus oxyacantha was performed. The in vivo cardioprotective potential of these medicinal plants was evaluated against surgically induced oxidative stress through left anterior descending coronary artery ligation (LADCA) in dogs. The antioxidant profiling of these plants was done through DPPH and DNA protection assay. The C. oxyacantha and T. arjuna showed maximum antioxidant potential, while the E. cardamom showed poor antioxidative strength even at its high concentration. Different concentrations of extracts of the said plants exhibited the protection of plasmid DNA against H2O2 damage as compared to the plasmid DNA merely treated with H2O2. The metabolomic profiling through LC-MS analysis of these antioxidants revealed the presence of active secondary metabolites responsible for their antioxidant potential. During in vivo analysis, blood samples of all treatment groups were drawn at different time intervals to analyze the cardiac and hemodynamic parameters. The results depicted that the group pretreated with HC4 significantly sustained the level of CK-MB, SGOT, and LDH as well as hemodynamic parameters near to normal. The histopathological examination also confirmed the cardioprotective potential of HC4. Thus, the HC4 being safe and inexpensive cardioprotective herbal combination could be considered as an alternate of synthetic drugs.