1. Sensor for Continuous and Real-Time Monitoring of Biomolecule Permeation Through Ultrathin Silicon Nanoporous Membranes
- Author
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Ananya Ghosh, Anju Chadha, V. T. Fidal, Enakshi Bhattacharya, Priyanka Bhadra, and Noel Prashant Ratchagar
- Subjects
chemistry.chemical_classification ,Photocurrent ,Materials science ,Silicon ,Biomolecule ,010401 analytical chemistry ,Analytical chemistry ,chemistry.chemical_element ,Chemical vapor deposition ,Permeation ,01 natural sciences ,0104 chemical sciences ,Membrane ,chemistry ,Electrical and Electronic Engineering ,Instrumentation ,Biosensor ,Bradford protein assay - Abstract
The increase in demand for continuous and real-time monitoring of permeation of biomolecules is addressed by using highly selective ultrathin silicon nanoporous membranes (SNMs) combined with detection using ultraviolet absorption. The membranes, with an average pore size of 8.8 nm, are fabricated using semiconductor batch processes including chemical vapor deposition and rapid thermal annealing. Bovine serum albumin (BSA) of a concentration of $250~\mu \text{g}$ /ml is used as the test molecule. The concentration of BSA diffused through the membrane is measured using optical transduction based in-house developed sensor. The photocurrent obtained from the sensor is measured every 15 min and compared with the standard Bradford assay at the same time-stamp. The concentration estimated by the sensor is found to agree with the Bradford assay with a standard deviation of 1.4%. The throughput of the membrane is increased by fabricating an array of SNMs, which showed an increase in diffusion rate by 3.8 times with respect to the single SNM. The clogging of pores by the biomolecules is analyzed using ionic conductivity experiments. The structural integrity of BSA diffused through the SNM is also analyzed.
- Published
- 2019
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