Udwesh Panda scite author profile

Recent advances in microfluidics-based point-of-care testing (POCT) technology such as paper, array, and beads have shown promising results for diagnosing various infectious diseases. The fast and timely detection of viral infection has proven to be a critical step for deciding the therapeutic outcome in the current COVID-19 pandemic, which in turn not only enhances the patient survival rate but also reduces the disease-associated comorbidities. In the present scenario, rapid, noninvasive detection of the virus using low cost and high throughput microfluidics-based POCT devices embraces the advantages over existing diagnostic technologies, for which a centralized lab facility, expensive instruments, sample pretreatment, and skilled personnel are required. Microfluidic-based multiplexed POCT devices can be a boon for clinical diagnosis in developing countries that lacks a centralized health care system and resources. The microfluidic devices can be used for disease diagnosis and exploited for the development and testing of drug efficacy for disease treatment in model systems. The havoc created by the second wave of COVID-19 led several countries’ governments to the back front. The lack of diagnostic kits, medical devices, and human resources created a huge demand for a technology that can be remotely operated with single touch and data that can be analyzed on a phone. Recent advancements in information technology and the use of smartphones led to a paradigm shift in the development of diagnostic devices, which can be explored to deal with the current pandemic situation. This review sheds light on various approaches for the development of cost-effective microfluidics POCT devices. The successfully used microfluidic devices for COVID-19 detection under clinical settings along with their pros and cons have been discussed here. Further, the integration of microfluidic devices with smartphones and wireless network systems using the Internet-of-things will enable readers for manufacturing advanced POCT devices for remote disease management in low resource settings.

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Cryopreservation: A Comprehensive Overview, Challenges, and Future Perspectives

Parihar

Kumar

Panda

et al. 2023

Advanced Biology

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Cryopreservation is the most prevalent method of long‐term cell preservation. Effective cell cryopreservation depends on freezing, adequate storage, and correct thawing techniques. Recent advances in cryopreservation techniques minimize the cellular damage which occurs while processing samples. This article focuses on the fundamentals of cryopreservation techniques and how they can be implemented in a variety of clinical settings. The article presents a brief description of each of the standard cryopreservation procedures, such as slow freezing and vitrification. Alongside that, the membrane permeating and nonpermeating cryoprotectants are briefly discussed, along with current advancements in the field of cryopreservation and variables influencing the cryopreservation process. The diminution of cryoinjury incurred by the cell via the resuscitation process will also be highlighted. In the end application of cryopreservation techniques in many fields, with a special emphasis on stem cell preservation techniques and current advancements presented. Furthermore, the challenges while implementing cryopreservation and the futuristic scope of the fields are illustrated herein. The content of this review sheds light on various ways to enhance the output of the cell preservation process and minimize cryoinjury while improving cell revival.

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Microfluidics-based devices and their role on point-of-care testing

Kumar

Panda

2022

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Clinically available/under trial drugs and vaccines for treatment of SARS-COV-2

Kumar

Parihar

Basha

et al. 2022

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Laser-Assisted Fabrication of Polymers by Pushing Down the Limit of Resolution

Kumar

Panda

Patel

et al. 2022

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This chapter deals with the latest manufacturing process, especially laser-based manufacturing of polymers with/without surface texturing, for their use in various fields of interest. Lasers have diverse applications in the fabrication of polymers. Lasers can be used from dry etching to soft lithography. This chapter is limited to exploration up to the fabrication of 3D micro/nanostructures in polymers using lasers. The wettability and optical response of these micro-textured polymers can easily be tuned through exposure to a laser of suitable wavelengths. Moreover, laser-assisted manufacturing can help produce extremely complex shapes. It is an excellent choice for functional prototypes, thermal applications, and end-use parts. Although laser-based manufacturing has many advantages that no other manufacturing process possesses, this process is not widely used or recommended. This chapter also extends the discussion to the issues/limitations with laser-based manufacturing and the type of materials being used. At the end, there shall be a discussion on the applications and scope of laser-assisted fabrication of polymers.

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Udwesh Panda

Microfluidics-Based Point-of-Care Testing (POCT) Devices in Dealing with Waves of COVID-19 Pandemic: The Emerging Solution

Cryopreservation: A Comprehensive Overview, Challenges, and Future Perspectives

Microfluidics-based devices and their role on point-of-care testing

Clinically available/under trial drugs and vaccines for treatment of SARS-COV-2

Laser-Assisted Fabrication of Polymers by Pushing Down the Limit of Resolution

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