Breathing exercises and pranayamas to decrease perceived exertion during breath-holding while locked-down due to COVID-19 online randomized study.

AIM: to compare anulom vilom pranayama (AVP), kapal bhati pranayama (KBP), diaphragmatic breathing exercises (DBE), and pursed-lip breathing (PLB) for breath holding time (BHT) and rating of perceived exertion (RPE). Methods- Participants were assessed for BHT and RPE, before training on any one intervention using online platforms, for one week during lockdown from COVID-19.15 participants in each group total N = 60 at- (α - 0.05), (1- ß - 0.90) & (effect size - 0.55); were analysed. Results - AVP & DBE decreased RPE (p < 0.000). KBP & PLB did not decrease RPE as compared to AVP & DBE (p. > 0.05). DBE increased BHT more than KBP & PLB interventions (p < 0.05), but not more than AVP (p > 0.05). One-way ANOVA of four interventions revealed significant variation for RPE change (p < 0.05), for AVP. Conclusions - AVP reduces RPE maximally during breath-holding, whereas DPE increases BHT more.

NMR Based Metabolomics: An Exquisite and Facile Method for Evaluating Therapeutic Efficacy and Screening Drug Toxicity.

Metabolomics is an analytical approach to metabolism and involves quantitative and comparative analysis of low-molecular-weight metabolites in body fluids or cellular/tissues extracts. Owing to its ability to reveal disease-specific metabolic patterns or metabolic changes produced in response to a therapeutic intervention; it is gaining widespread applications virtually in all aspects of biomedical and pharmaceutical research pertaining to human healthcare management. It has also started playing a strategic role in pharmacological and toxicological research for evaluating therapeutic efficacy/safety of promising drug candidates either alone or in conjunction with other omics tools such as genomics, transcriptomics and proteomics. The metabolic profiling capabilities of nuclear magnetic resonance (NMR) spectroscopy along with pattern recognition methods have successfully been applied for identifying a diagnostic panel of biomarkers, evaluating drug efficacy/safety, screening toxicity and disease mechanism. Particularly, the interest in applying NMR-based metabolomics for the assessment of therapeutic efficacy and safety is increasing among drug researchers and drug regulators owing to its nondestructive, non-selective and minimal sample preparation requirement. On top of this, it offers the potential for high-throughput (i.e. >100 samples a day is attainable) and provides highly reproducible results. In this review, we will discuss some of the recent developments related to NMR based metabolomics followed by some recent literature examples to highlight its potential in (a) the evaluation of therapeutic efficacy and safety of lead discovery compounds, (b) monitoring disease status and recovery after treatment and (c) identification and evaluation of biomarkers of systemic/organ-specific toxicity. Additionally, the review will also highlight its role to facilitate clinical trial testing and improve post-approval drug monitoring.

Prospects of Bacteriotherapy with Nanotechnology in Nanoparticledrug Conjugation Approach for Cancer Therapy.

Bacteriotherapy and nanotechnology have shown remarkable potential in diagnostic and therapeutic applications for various diseases. Individual impacts of these micro-nano systems over different aspects of human health are well studied; however, an integrated system of bacteria-nanoparticle (NP) conjugation is less explored. The untamed potential of bacteria-NP conjugation could be a new tool for diagnosis and treatment of invasive diseases like malaria, tuberculosis and cancer. Mammalian cells exhibit cytosis as their defense mechanism when they encounter foreign elements such as bacteria. In these mammalian cells, during phagocytosis, bacteria are ruptured and lysed by lysozymes. A bacterium carrying the drug-tagged NP would be engulfed in the same manner and ultimately reaches the target cells. Rapid and continuous cell divisions in the cancer tissues lead to defective vessels, underdeveloped cellcell interconnects, development of hypoxic areas and heterogeneous population of tumor cells. This unorganized and poorly developed angiogenesis in tumor cells makes it difficult for conventional chemotherapeutic drugs to localize the tumors selectively. In the present scenario of diagnosis and treatment of cancer/tumor cells, it could be expected that the existing bacteriotherapy with the advanced nanotechnology would be a way further in the targeted drug delivery for cancer therapy. This review emphasizes the potential applications of bacteriotherapy with nanotechnology for the diagnosis and treatment of cancer.