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A paper microfluidic device based colorimetric sensor for the detection and discrimination of elapid versus viper envenomation. / Ramana, Lakshmi; Mathapati, Santosh S.; Salvi, Nitin et al.
In: Analyst, Vol. 147, No. 4, 21.02.2022, p. 685-694.

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Ramana, L, Mathapati, SS, Salvi, N, Khadilkar, MV, Malhotra, A, Santra, V & Sharma, TK 2022, 'A paper microfluidic device based colorimetric sensor for the detection and discrimination of elapid versus viper envenomation', Analyst, vol. 147, no. 4, pp. 685-694. https://doi.org/10.1039/D1AN01698A

APA

Ramana, L., Mathapati, S. S., Salvi, N., Khadilkar, M. V., Malhotra, A., Santra, V., & Sharma, T. K. (2022). A paper microfluidic device based colorimetric sensor for the detection and discrimination of elapid versus viper envenomation. Analyst, 147(4), 685-694. https://doi.org/10.1039/D1AN01698A

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MLA

VancouverVancouver

Ramana L, Mathapati SS, Salvi N, Khadilkar MV, Malhotra A, Santra V et al. A paper microfluidic device based colorimetric sensor for the detection and discrimination of elapid versus viper envenomation. Analyst. 2022 Feb 21;147(4):685-694. Epub 2021 Dec 20. doi: 10.1039/D1AN01698A

Author

Ramana, Lakshmi ; Mathapati, Santosh S. ; Salvi, Nitin et al. / A paper microfluidic device based colorimetric sensor for the detection and discrimination of elapid versus viper envenomation. In: Analyst. 2022 ; Vol. 147, No. 4. pp. 685-694.

RIS

TY - JOUR

T1 - A paper microfluidic device based colorimetric sensor for the detection and discrimination of elapid versus viper envenomation

AU - Ramana, Lakshmi

AU - Mathapati, Santosh S.

AU - Salvi, Nitin

AU - Khadilkar, M.V.

AU - Malhotra, Anita

AU - Santra, Vishal

AU - Sharma, Tarun Kumar

PY - 2022/2/21

Y1 - 2022/2/21

N2 - Snake bites are a neglected tropical disease, causing mortality and severe damage to various vital organs like the nervous system, kidneys and heart. There is increasing interest in designing new antivenom treatments that are more specific to particular groups (either taxonomic or regional) of species, given the increasing evidence that current polyvalent Indian antivenom is ineffective in many situations. Under these circumstances, being able to detect the species, or a group of species, responsible for the envenomation becomes important. Unfortunately, no such diagnostic tool is available in the Indian market. Such a tool will need to be rapid, sensitive and affordable. To address this need, we have combined the power of nanotechnology and paper microfluidics and herein report a device that has the ability to detect and differentiate viper venom from elapid and scorpion venom. In principle, this assay is based on the release of the dye from the stimuli-responsive glutaraldehyde cross-linked methylene blue-loaded gelatin (GMG) nanoparticles in the presence of snake venom metalloproteases and serine proteases. The developed equipment-free assay can detect and discriminate viper venom from that of elapids and scorpions. The low-end detection limit of the sensor is ∼3.0 ng for the saw-scaled viper Echis carinatus, while the same for Russell's viper Daboia russelii is ∼6.0 ng. The performance of the sensor remains unaltered for different batches of GMG nanoparticles. Altogether, this finding establishes the role of nanotechnology and paper microfluidics in the rapid and accurate detection of viper venom.

AB - Snake bites are a neglected tropical disease, causing mortality and severe damage to various vital organs like the nervous system, kidneys and heart. There is increasing interest in designing new antivenom treatments that are more specific to particular groups (either taxonomic or regional) of species, given the increasing evidence that current polyvalent Indian antivenom is ineffective in many situations. Under these circumstances, being able to detect the species, or a group of species, responsible for the envenomation becomes important. Unfortunately, no such diagnostic tool is available in the Indian market. Such a tool will need to be rapid, sensitive and affordable. To address this need, we have combined the power of nanotechnology and paper microfluidics and herein report a device that has the ability to detect and differentiate viper venom from elapid and scorpion venom. In principle, this assay is based on the release of the dye from the stimuli-responsive glutaraldehyde cross-linked methylene blue-loaded gelatin (GMG) nanoparticles in the presence of snake venom metalloproteases and serine proteases. The developed equipment-free assay can detect and discriminate viper venom from that of elapids and scorpions. The low-end detection limit of the sensor is ∼3.0 ng for the saw-scaled viper Echis carinatus, while the same for Russell's viper Daboia russelii is ∼6.0 ng. The performance of the sensor remains unaltered for different batches of GMG nanoparticles. Altogether, this finding establishes the role of nanotechnology and paper microfluidics in the rapid and accurate detection of viper venom.

U2 - 10.1039/D1AN01698A

DO - 10.1039/D1AN01698A

M3 - Article

VL - 147

SP - 685

EP - 694

JO - Analyst

JF - Analyst

SN - 0003-2654

IS - 4

ER -