Sustainable chemical preventive models in COVID-19: Understanding, innovation, adaptations, and impact

Progress in COVID research and developments during pandemic

The pandemic respiratory disease COVID-19 has spread over the globe within a small span of time. Generally, there are two important points are being highlighted and considered towards the successful diagnosis and treatment process. The first point includes the reduction of the rate of infections and the next one is the decrease of the death rate. The major threat to public health globally progresses due to the absence of effective medication and widely accepted immunization for the COVID-19. Whereas, understanding of host susceptibility, clinical features, adaptation of COVID-19 to new environments, asymptomatic infection is difficult and challenging. Therefore, a rapid and an exact determination of pathogenic viruses play an important role in deciding treatments and preventing pandemic to save the people's lives. It is urgent to fix a standardized diagnostic approach for detecting the COVID-19. Here, this systematic review describes all the current approaches using for screening and diagnosing the COVID-19 infectious patient. The renaissance in pathogen due to host adaptability and new region, facing creates several obstacles in diagnosis, drug, and vaccine development process. The study shows that adaptation of accurate and affordable diagnostic tools based on candidate biomarkers using sensor and digital medicine technology can deliver effective diagnosis services at the mass level. Better prospects of public health management rely on diagnosis with high specificity and cost-effective manner along with multidisciplinary research, specific policy, and technology adaptation. The proposed healthcare model with defined road map represents effective prognosis system.

Advances in Organ-on-a-Chip Materials and Devices

The organ-on-a-chip (OoC) paves a way for biomedical applications ranging from preclinical to clinical translational precision. The current trends in the in vitro modeling is to reduce the complexity of human organ anatomy to the fundamental cellular microanatomy as an alternative of recreating the entire cell milieu that allows systematic analysis of medicinal absorption of compounds, metabolism, and mechanistic investigation. The OoC devices accurately represent human physiology in vitro; however, it is vital to choose the correct chip materials. The potential chip materials include inorganic, elastomeric, thermoplastic, natural, and hybrid materials. Despite the fact that polydimethylsiloxane is the most commonly utilized polymer for OoC and microphysiological systems, substitute materials have been continuously developed for its advanced applications. The evaluation of human physiological status can help to demonstrate using noninvasive OoC materials in real-time procedures. Therefore, this Review examines the materials used for fabricating OoC devices, the application-oriented pros and cons, possessions for device fabrication and biocompatibility, as well as their potential for downstream biochemical surface alteration and commercialization. The convergence of emerging approaches, such as advanced materials, artificial intelligence, machine learning, three-dimensional (3D) bioprinting, and genomics, have the potential to perform OoC technology at next generation. Thus, OoC technologies provide easy and precise methodologies in cost-effective clinical monitoring and treatment using standardized protocols, at even personalized levels. Because of the inherent utilization of the integrated materials, employing the OoC with biomedical approaches will be a promising methodology in the healthcare industry.

COVID-19 Immunosensors techniques: Reframing policy and strategic development goals for the post-COVID-19 scenario

The World in the present scenario is facing a global threat that can be designated as – The Chain of Multidimensional Crises—affecting possibly every sector with some major vulnerabilities ranging from healthcare areas, educational sector, value chain production areas, financial and networking lineages, mass-transit systems, agri sector, and finally the ecology. Further this pandemic has resulted in a failure cascade mechanism affecting every possible system threatening the livelihoods of the existing population. In addition, has also increased the risk and potential transmission of the dreadful disease bridging gaps in terms of clinical diagnosis due to the quick antigenic shift and drifts recorded in corona virus. These degradations affecting the world globally must be managed sustainably in the post-COVID era to finally recover from the witnessed COVID 19 losses and degradation in every sphere, so that it heals up in supporting the present as well as the needs of future generations. Therefore, in order to deal with the losses due to COVID-19 pandemic, synergistic and strongly integrated approaches/policies are needed to firmly answer and heal up the world globally in terms of social, economic, and ecological scenario, respectively. Furthermore, Sustainable Development Goals (SDG's) are thus needed for reframing the sustainable recoveries from COVID 19 pandemic. The present paper thus discusses the support/policies which need to be framed in the post-COVID phase which can assist the Governmental agencies and coherent policy makers to ensure a sustainable recovery pattern incorporated with SDG's to finally fill the loopholes and gaps created by this pandemic havoc.

Role of nanotechnology for coronavirus detection

The Coronavirus disease 2019 (COVID-19) is the worst pandemic faced by the mankind in current millennium. It is due to the highly contagious severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). This was detected for the first time in December 2019 with rapid human-to-human transmission. The global pandemic has spread out across 213 countries by affecting millions including 52.7 lakh death. Currently, there are no clinically proven therapeutic methods that clearly inhibit the effects of this virus. Nanoparticles (NPs) have been widely used in many medical applications, such as biosensing, drug delivery, imaging, and antimicrobial treatment. Looking the rapid, cost effective and accurate sensing of the virus, the field of nanoscience and nanotechnology is working actively. By following the colorimetric method and surface plasmon spectroscopy, several nanoparticles are used in quantifying and detecting the COVID-19. This chapter contains the rapid analysis and quantification of COVID-19 by the arrangements of several nanoparticles including gold nanoparticles, iron oxide nanoparticles, etc.