Development and recent advancement in microfluidics for point of care biosensor applications: A review

Capillaries are small microscopic channels found in nature predominantly. These flow blood in animals and food, water and nutritions in plants. Mimicking these capillaries scientist discovered the micro channels and named the related study as microfluidics. These microscopic channels/capillaries hav...

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Published inBiosensors and bioelectronics. X Vol. 11; p. 100218
Main Authors Lakhera, Praveen, Chaudhary, Vikas, Bhardwaj, Bhavishya, Kumar, Parveen, Kumar, Sanjeev
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.09.2022
Elsevier
Subjects
Biomedical applications
Biosensor
Capillary
Microfluidics
Point-of-care device
Biomedical applications
Point-of-care device
Biosensor
Microfluidics
Capillary
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Abstract Capillaries are small microscopic channels found in nature predominantly. These flow blood in animals and food, water and nutritions in plants. Mimicking these capillaries scientist discovered the micro channels and named the related study as microfluidics. These microscopic channels/capillaries have wide applications in the area of biomedical instrumentations. Microfluidics work on the combined principles of fluid dynamics, biology, chemistry, microelectronics, physics, and material science. The artificial microfluidics or capillaries can be fabricated using various techniques such as xurography, laser cutting, photolithography, injection moulding, and fast lithographic Activation of Sheets (FLASH). Capillaries have tremendous application, especially in biosensors; from sample collection to the detection of various biomolecules such as nucleic acids, proteins, carbohydrates, lipids, other metabolites, etc. This work presents a comprehensive review of the journey of capillary development, milestones achieved, and recent advancements in the area of microfluidics-based biosensors. This review is focused to meet the requirements of the researchers engaged in designing, simulating, and fabricating capillaries for the desired applications. Special insights have been given on the opportunities and challenges in capillary development. •Microfluidics based bio-sensing for the detection of different biomarker.•Challenges and Opportunities during Microfluidics fabrication and development.•Commercially available Point of care devices using Capillary.
AbstractList Capillaries are small microscopic channels found in nature predominantly. These flow blood in animals and food, water and nutritions in plants. Mimicking these capillaries scientist discovered the micro channels and named the related study as microfluidics. These microscopic channels/capillaries have wide applications in the area of biomedical instrumentations. Microfluidics work on the combined principles of fluid dynamics, biology, chemistry, microelectronics, physics, and material science. The artificial microfluidics or capillaries can be fabricated using various techniques such as xurography, laser cutting, photolithography, injection moulding, and fast lithographic Activation of Sheets (FLASH). Capillaries have tremendous application, especially in biosensors; from sample collection to the detection of various biomolecules such as nucleic acids, proteins, carbohydrates, lipids, other metabolites, etc. This work presents a comprehensive review of the journey of capillary development, milestones achieved, and recent advancements in the area of microfluidics-based biosensors. This review is focused to meet the requirements of the researchers engaged in designing, simulating, and fabricating capillaries for the desired applications. Special insights have been given on the opportunities and challenges in capillary development. •Microfluidics based bio-sensing for the detection of different biomarker.•Challenges and Opportunities during Microfluidics fabrication and development.•Commercially available Point of care devices using Capillary.
Capillaries are small microscopic channels found in nature predominantly. These flow blood in animals and food, water and nutritions in plants. Mimicking these capillaries scientist discovered the micro channels and named the related study as microfluidics. These microscopic channels/capillaries have wide applications in the area of biomedical instrumentations. Microfluidics work on the combined principles of fluid dynamics, biology, chemistry, microelectronics, physics, and material science. The artificial microfluidics or capillaries can be fabricated using various techniques such as xurography, laser cutting, photolithography, injection moulding, and fast lithographic Activation of Sheets (FLASH). Capillaries have tremendous application, especially in biosensors; from sample collection to the detection of various biomolecules such as nucleic acids, proteins, carbohydrates, lipids, other metabolites, etc. This work presents a comprehensive review of the journey of capillary development, milestones achieved, and recent advancements in the area of microfluidics-based biosensors. This review is focused to meet the requirements of the researchers engaged in designing, simulating, and fabricating capillaries for the desired applications. Special insights have been given on the opportunities and challenges in capillary development.
ArticleNumber 100218
Author Bhardwaj, Bhavishya
Lakhera, Praveen
Kumar, Parveen
Kumar, Sanjeev
Chaudhary, Vikas
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Keywords Biomedical applications
Point-of-care device
Biosensor
Microfluidics
Capillary
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Snippet Capillaries are small microscopic channels found in nature predominantly. These flow blood in animals and food, water and nutritions in plants. Mimicking these...
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SubjectTerms Biomedical applications
Biosensor
Capillary
Microfluidics
Point-of-care device
Title Development and recent advancement in microfluidics for point of care biosensor applications: A review
URI https://dx.doi.org/10.1016/j.biosx.2022.100218
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