W J Skal

The digital nobility and the elite are tapping into people's vagus nerve for a bi-directional wireless communication mechanism for the Internet of BioNano Things (IoBNT). They are utilizing the gut-biome-brain-axis to control the mind thru the gut and vice versa. Microbiome-Gut-Brain Axis (MGBA) as a Biomolecular Communication Network for the Internet of Bio-NanoThings This article discusses the utilization of the MGBA as an IoBNT communication network infrastructure to transmit and receive information generated by and/or directed to electronic and biological devices where this infrastructure is also envisioned to communicate with the external environment through dedicated molecular (alimentary canal) and electrical (wireless data transfer through skin) interfaces. https://t.co/NZJyf3hvgO Synthetic Molecular Communication (MC) via Biological Transmitters: Therapeutic Modulation of the Gut-Brain Axis Synthetic molecular communication (SMC) is a key enabler for future healthcare systems in which Internet of Bio-Nano-Things (IoBNT) devices facilitate the continuous monitoring of a patient’s biochemical signals. To close the loop between sensing and actuation in these systems, both the detection and the generation of in-body molecular communication (MC) signals is key. However, generating signals inside the human body, e.g., via synthetic nanodevices, still poses a major research challenge in SMC, due to technological obstacles as well as legal, safety, and ethical issues. In contrast to many existing studies, this paper considers an SMC system in which signals are generated indirectly via the modulation of a natural in-body MC system, namely the gut-brain axis (GBA). We propose to leverage personal health data, e.g., data gathered by in-body IoBNT devices, to overcome this research gap and design more versatile and robust GBA modulation-based treatments as compared to the existing ones. To show the feasibility of our approach, we first define a catalog of theoretical requirements for therapeutic GBA modulation. Then, we propose a machine learning model to verify these requirements for practical scenarios when only limited data on the GBA modulation is available. By evaluating the proposed model on several published datasets, we confirm its excellent accuracy in identifying different modulators of the GBA. Finally, we utilize the proposed model to identify specific modulatory pathways that play an important role for therapeutic GBA modulation. https://t.co/gc76D1NTy6