Supratim Ray scite author profile

Hyperactivation of immune responses resulting in excessive release of pro-inflammatory mediators in alveoli/lung structures is the principal pathological feature of coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). The cytokine hyperactivation in COVID-19 appears to be similar to those seen in rheumatoid arthritis (RA), an autoimmune disease. Emerging evidence conferred the severity and risk of COVID-19 to RA patients. Amid the evidence of musculoskeletal manifestations involving immune-inflammation-dependent mechanisms and cases of arthralgia and/or myalgia in COVID-19, crosstalk between COVID-19 and RA is often debated. The present article sheds light on the pathological crosstalk between COVID-19 and RA, the risk of RA patients in acquiring SARS-CoV-2 infection, and the aspects of SARS-CoV-2 infection in RA development. We also conferred whether RA can exacerbate COVID-19 outcomes based on available clinical readouts. The mechanistic overlapping in immune-inflammatory features in both COVID-19 and RA was discussed. We showed the emerging links of angiotensin-converting enzyme (ACE)-dependent and macrophage-mediated pathways in both diseases. Moreover, a detailed review of immediate challenges and key recommendations for anti-rheumatic drugs in the COVID-19 setting was presented for better clinical monitoring and management of RA patients. Taken together, the present article summarizes available knowledge on the emerging COVID-19 and RA crosstalk and their mechanistic overlaps, challenges, and therapeutic options.

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Carbon Nanomaterials for Drug Delivery and Cancer Therapy

Chakrabarti¹,

Kiseleva²,

Vertegel³

et al. 2015

j nanosci nanotechnol

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Nanotechnology is one of the most exciting disciplines and it incorporates physics, chemistry, materials science, and biology. It can be applied to design cancer medicines with improved therapeutic indices. At the basic level, carbon nanotubes (CNTs) and graphene are sp2 carbon nanomaterials. Their unique physical and chemical properties make them interesting candidates of research in a wide range of areas including biological systems and different diseases. Recent research has been focused on exploring the potential of the CNTs as a carrier or vehicle for intracellular transport of drugs, proteins, and targeted genes in vitro and in vivo. Several research groups are actively involved to find out a functional CNT carrier capable of transporting targeted drug molecules in animal models with least toxicity. Current investigations are also focused on graphene, an allotrope of carbon, which appears to be a promising agent for successful delivery of biomolecules in various animal models. But potential clinical implementations of CNTs are still hampered by distinctive barriers such as poor bioavailability and intrinsic toxicity, which pose difficulties in tumor targeting and penetration as well as in improving therapeutic outcome. This article presents recent progresses in the design and evaluation of closely related CNTs for experimental cancer therapy and explores their implications in bringing nanomedicines into the clinics.

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Glutamic acid as anticancer agent: An overview

Dutta¹,

Ray²,

Nagarajan

2013

Saudi Pharmaceutical Journal

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The objective of the article is to highlight various roles of glutamic acid like endogenic anticancer agent, conjugates to anticancer agents, and derivatives of glutamic acid as possible anticancer agents. Besides these emphases are given especially for two endogenous derivatives of glutamic acid such as glutamine and glutamate. Glutamine is a derivative of glutamic acid and is formed in the body from glutamic acid and ammonia in an energy requiring reaction catalyzed by glutamine synthase. It also possesses anticancer activity. So the transportation and metabolism of glutamine are also discussed for better understanding the role of glutamic acid. Glutamates are the carboxylate anions and salts of glutamic acid. Here the roles of various enzymes required for the metabolism of glutamates are also discussed.

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Kinetics of transformation of delta ferrite during creep in a type 316(N) stainless steel weld metal

Sasikala

Ray

Mannan

2003

Materials Science and Engineering: A

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Supratim Ray

Bacteriocin plasmids ofPediococcus acidilactici

COVID-19 and Rheumatoid Arthritis Crosstalk: Emerging Association, Therapeutic Options and Challenges

Carbon Nanomaterials for Drug Delivery and Cancer Therapy

Glutamic acid as anticancer agent: An overview

Kinetics of transformation of delta ferrite during creep in a type 316(N) stainless steel weld metal

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