Under The Skin: The Internet Of Bio-Nano Things

First, there was the Internet of Things (IoT), then the Internet of Bodies (IoB), the Internet of Everything (IoE), and finally, Big Pharma and the military are going into your blood to construct the Internet of Bio-NanoThings (IoBNT). You might have hoped for the Internet of Nothing, but instead, you are getting the Internet Of Universal Skynet (IoUS).

This paper from March 2015 is a primer that anybody can understand, including you. The IoBNT is the final building block of the surveillance network, bridging all living things from the biochemical domain into the electrical domain of the Internet.

There was no warning that nanotechnology of this sort was being pumped into your veins when you received a mRNA injectable from Pfizer or Moderna. Not a word from the government, Big Pharma, or the Military. There was no Informed Consent offered. The non-stop propaganda blared “Safe and Effective.”

Technocracy is literally on track to conquer the human race, while humans don’t have a clue that a war is being waged against them in the first place. This is the topic of OMNIWAR: A SYMPOSIUM on September 21. I will be participating with Catherine Austin Fitts, David Hughes, Daniel Broudy and Lissa Johnson. It is free but you should RSVP to get further notices. This is the first global livestream that will reach all corners of the world. Can you see why I am asking to shout it from the roof top? ⁃ Patrick Wood, Editor.

The IoBNT stands as a paradigm-shifting concept for communication and network engineering, where novel challenges are faced to develop efficient and safe techniques for the exchange of information, interaction, and networking within the biochemical domain while enabling an interface to the electrical domain of the Internet.

Abstract

The Internet of Things (IoT) has become an important research topic in the last decade, where things refer to interconnected machines and objects with embedded computing capabilities employed to extend the Internet to many application domains. While research and development continue for general IoT devices, there are many application domains where very tiny, concealable, and non-intrusive Things are needed.

The properties of recently studied nanomaterials, such as graphene, have inspired the concept of Internet of NanoThings (IoNT), based on the interconnection of nanoscale devices. Despite being an enabler for many applications, the artificial nature of IoNT devices can be detrimental where the deployment of NanoThings could result in unwanted effects on health or pollution. The novel paradigm of the Internet of Bio-Nano Things (IoBNT) is introduced in this paper by stemming from synthetic biology and nanotechnology tools that allow the engineering of biological embedded computing devices.

Based on biological cells, and their functionalities in the biochemical domain, Bio-NanoThings promise to enable applications such as intra-body sensing and actuation networks, and environmental control of toxic agents and pollution. The IoBNT stands as a paradigm-shifting concept for communication and network engineering, where novel challenges are faced to develop efficient and safe techniques for the exchange of information, interaction, and networking within the biochemical domain, while enabling an interface to the electrical domain of the Internet.

Introduction

The Internet of Things (IoT) defines a cyber physical paradigm, where all types of real-world physical elements (sensors, actuators, personal electronic devices, or home appliances, among others) are connected, and are able to autonomously interact with each other. This new form of seamless connectivity is the enabler for many applications such as machine to machine communication, real time monitoring of industrial processes, smart cities, smart grids for energy management, intelligent transportation, environmental monitoring, infrastructure management, medical and healthcare systems, building and home automation, and large scale deployments. The Internet of Things became a focus for research and development in the last 15 years. A large amount of investments for Internet of Things was and is still being made by government agencies and industry worldwide.

Recently, the concept of IoT has been revised in light of novel research advances made in the field of nanotechnology and communication engineering, which enable the development of networks of embedded computing devices, based on nanomaterials such as graphene or metamaterials, having scales ranging from one to a few hundred nanometers, called nanothings. The Internet of NanoThings (IoNT), introduced for the first time in [1], is proposed as the basis of numerous future applications, such as in the military, healthcare, and security fields, where the nanothings, thanks to their limited size, can be easily concealed, implanted, and scattered in the environment, where they can cooperatively perform sensing, actuation, processing, and networking.

While nanothings can push the engineering of devices and systems to unprecedented environments and scales, similarly to other devices, they have an artificial nature, since they are based on synthesized materials, electronic circuits, and interact through electromagnetic (EM) communications [1]. These characteristics can be detrimental for some application environments, such as inside the body or in natural ecosystems, where the deployment of nanothings and their EM radiation could result in unwanted effects on health or pollution.