Evaluating Gut Microbiota Modification as a Next-Generation Therapy for Obesity and Diabetes.

The human body is a complex ecosystem that thrives on symbiosis. It is estimated that around 10^14 commensal microorganisms inhabit the human body, with the gut microbiota being one of the most diverse and complex populations of bacteria. This community is thought to comprise over a thousand different species that play a crucial role in the development of critical human diseases such as cancer, obesity, diabetes, mental depression, hypertension, and others. The gut microbiota has been identified as one of the most recent contributors to these metabolic disorders. With the emergence of inexpensive and high-performance sequence technology, our understanding of the function of the intestinal microbiome in host metabolism regulation and the development of (cardio) metabolic diseases has increased significantly. The symbiotic relationship between the gut microbiota and the host is essential for properly developing the human metabolic system. However, if this balance is disrupted by various factors such as infection, diet, exercise, sleep patterns, or exposure to antibiotics, it can lead to the development of various diseases in the body, including obesity and diabetes type 1 and 2. While many approaches and medications have been developed globally to treat these diseases, none have proven to be entirely effective, and many show side effects. Therefore, scientists believe that treating the gut microbiota using tried-and-true methods is the best option for combating obesity and diabetes. In this study, we aim to identify several feasible ways and prospects for gut microbiota therapy that can shape a new format for the treatment of obesity and diabetes.

Severe acute respiratory syndrome coronavirus 2 invasion in the central nervous system: a host-virus deadlock.

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) devastation on the central nervous system (CNS) is ascertained by the present clinical findings and the noticeable signs and symptoms. The CNS involvement of the virus is not trivial; although the brain has highly protective systems, the virus has ways to breach them with a destructive potential. For successful entry of the virus, different possible routes with favorable mechanisms are used. The SARS-CoV-2 invasion induces a mechanism of both the innate and adaptive immune response to control virus replication and removal from the CNS tissues. The cytokine storm and autoimmune response during the immunological events result in demyelination, damage of resident cells and neurons, cerebrovascular thrombosis, and dysregulation of neuro signaling pathways. Furthermore, hypoxia and toxemia accelerate the neurological destruction process. The acute attributions on psychology due to inflammation is a hallmark of CNS involved pathogenesis; nevertheless, the productivity, durability, and longevity of virus-specific lymphocytes are the vital indicators for complete removal of viral antigen and in combat against reinfection of the CNS. Keywords: CNS invasion; immune response; cytokine storm; demyelination; mental status.