Achieving Longevity in Wireless Body Area Network by Efficient Transmission Power Control for IoMT Applications

The application of tiny body sensors to collect, process, store, analyze, and retrieve medical information from a human body is a part of the Internet of Medical Things (IoMT).  IoMT helps to monitor and track human vital health parameters, predict disease, notify the patients and the health care professionals with relevant data for analyzing the problems before they become severe and for earlier invention. By 2022, more than 60 % of IoT applications will be health-related. The convergence of biomedical sensors, wireless body area networks (WBAN), Information technology, and bioinformatics will help improve the efficiency of saving human lives. In a WBAN, network longevity is challenging because of the limited supply of low power battery energy in tiny body sensor nodes. Here, we proposed an energy-efficient transmission power control (TPC) algorithm to extend the network lifetime in IoMT networks for healthcare applications by eliminating the transceiver overhearing problem. In TPC, human tissue resistivity properties are considered to adjust the transmission power, which reduces the communication power and extends the network lifetime. The simulation results show that network power consumption is reduced by 35%

Achieving Longevity in Wireless Body Area Network by Efficient Transmission Power Control for IoMT Applications

The application of tiny body sensors to collect, process, store, analyze, and retrieve medical information from a human body is a part of the Internet of Medical Things (IoMT).  IoMT helps to monitor and track human vital health parameters, predict disease, notify the patients and the health care professionals with relevant data for analyzing the problems before they become severe and for earlier invention. By 2022, more than 60 % of IoT applications will be health-related. The convergence of biomedical sensors, wireless body area networks (WBAN), Information technology, and bioinformatics will help improve the efficiency of saving human lives. In a WBAN, network longevity is challenging because of the limited supply of low power battery energy in tiny body sensor nodes. Here, we proposed an energy-efficient transmission power control (TPC) algorithm to extend the network lifetime in IoMT networks for healthcare applications by eliminating the transceiver overhearing problem. In TPC, human tissue resistivity properties are considered to adjust the transmission power, which reduces the communication power and extends the network lifetime. The simulation results show that network power consumption is reduced by 35%

Role of quaternary ammonium compound immobilized metallic graphene oxide in PMMA/PEG membrane for antibacterial, antifouling and selective gas permeability properties

Recently, there is a high demand for development of polymeric membrane for their widespread technological applications. Polymer blends incorporation with inorganic composite particles is the most effective strategy for obtaining antifouling, antibacterial, gas and water permeable membrane materials. However, their biological and surface properties are always hindered by the inefficient interaction of filler into polymer matrix because it is distributed into the bulk membrane matrix. In this study, graphene oxide nanosheets are incorporated with metal (Ag)/metal oxide (ZnO) composite filler (MGO) followed by surface modification with quaternary cetyltrimethylammonium bromide (CTAB) to enhance non-covalent interactions between filler and poly methyl methacrylate (PMMA)/polyethylene glycol (PEG) blend membrane. The membrane was utilized for improving antifouling, antibacterial and gas permeability of membrane. Our results indicated that CTAB-modified filler (CTAB@MGO) was bonded to the polymer blend membrane without affecting the membranes’ physicochemical properties. The prepared CTAB@MGO–PMMA/PEG membrane showed excellent antibacterial property against model Escherichia coli bacteria. The antifouling activity and CTAB stability results of modified blend membrane ensured reduced bovine serum albumin adsorption and slow dissociation of surfactant molecules, respectively. The CTAB@MGO–PMMA/PEG blend membrane also showed promising gas permeability results with hydrogen (H2), nitrogen (N2) and carbon dioxide (CO2). The presented approach highlights the potential of surface modification of filler and introduces them in polymeric membrane as a simple, easy and cost-effective strategy for preparing antifouling and gas/water permeable polymeric membranes