Protocol Design for Evaluating the Immunity of Bivalve Fluids From Anodonta Cygnea in SARS and COVID-19

A deep and consistent study will be developed with an increase in the human sampling for better understanding the intervention efficacy of this intelligence medicine integrator, the Mora® Nova method. These in silico experiments when associated with the bioresonance frequencies from stimulated hemolymph compounds of the freshwater bivalve A. cygnea, may lead us to expect high plasticity and immunological potential.

Obviously, additional in vitro studies in future, with adequate culture cell lineages in different conditions and with bioresonance treatment by Mora® Nova method, should also be accomplished with hemolymph/plasma interference to confirm the pertinence, and the real efficacy on SARS / COVID-19 infection as well as to clarify the respective biological mechanisms.

In addition, to analyze and evaluate any specific bioactive compound from the induced hemolymph condition needs molecular experiments which can give deep structural information concerning any efficient molecule against the SARS / COVID-19 virus lineage and respective mutants. Effectively, according to current scientific opinion, the virus mutation phenomenon leads to great and problematic difficulty for maintaining the collective and human global immunization. In this case, the present Mora methodology offers a very functional, dynamic, and efficient process when combined with a biological model, as the bivalve A. cygnea, with high plasticity and eventual molecular reconstructive adaptation. This Mora procedure can extend to other immune-depressive diseases namely cancer, rheumatoid arthritis, and neurodegenerative diseases combining with respective stimulated bivalve fluids. It suggests opening a promising future perspective when applied to large human sampling as well as with in vitro cellular assays.

In addition, to explore this research with in vitro cell cultures and to do the characterization and the effects from bio-compounds on similar diseases is our close objective.