The new non-metallic microchips allow biocompatible microchip production.

MIT researchers are developed metal-free material that can use in biocompatible microchips. And that thing can make the new type of microchip implants possible. Those systems can create by using printers, and they can be more flexible than ever before. 

The development of microchips that can implant in the human body is changing many things. Those microchips can use to control prostheses, they can connect people straight to computers. And those systems can also make it possible that humans can control animals by implanting them with microchips. These types of systems are the next-generation tools for communication. And those microchips allow communication between people by using a way called technical telepathy. 

Those microchips can connect people to the Internet. The user can connect those microchips to a regular cell phone. And that allows transmitting EEG curves over long distances. The microchip that is connected to the brain's visual center can communicate with an action camera. 

That camera can implant in the place where is a blinded eye. Or those cameras can use similar technology that is used in spy cameras. And they can be in the sunglasses headband. That kind of system can give stereo vision to a person whose eyes are not working normally.

The problem with implanted microchips and things like eye implants is an immune reaction. The solution to that problem could be that researchers can cover those microchips by using the user's own cloned cells. The artificial blood veins can use to cover microchips and microchips that deny immune rejection. 

"MIT engineers have created a soft, conductive polymer hydrogel that could serve as a biocompatible, metal-free implantable electrode. The material, which can be made into printable ink, might be used in a variety of medical applications, such as pacemakers and deep-brain stimulators. It has shown promise in preliminary animal tests for maintaining stability and effectively transmitting electrical pulses, with less inflammation and scarring compared to traditional metal electrodes." (ScitechDaily.com/Biocompatible Innovation: MIT’s Soft, Printable, Metal-Free Electrodes for Next-Gen Implants)

Researchers can put metal wires in blood veins. The cells that form blood veins can also use for covering microchips. If those biological cables are made using cloned cells that are grown in cell cultures are taken from the receiver that denies the rejection. Those cloned blood veins can also use with MIT's new material. 

New non-metallic microchips are revolutionizing technology, used in microchip implants. In visions, the microchip is covered by a person's tissue cells that decrease the rejection. The extremely thin microchips can install on bones like skulls, and they can get information from the brain areas that are responsible for things like moving limbs. In that case, the medical staff can install microchips on the skull. That denies the need for complicated surgery. 

The system can get its electricity from the batteries that are used in pacemakers or straight from the nervous system. The biological batteries like cells that create electricity can use to deliver energy to those microchips. In that case, the biological electric unit uses the same nutrients as humans. And that kind of battery can give electricity for the person's entire lifetime. 

That kind of microchip can control things like robot arms. But they can also use to fix damage in the nervous system. 

And they can put another microchip at the point where the damage in the nervous system is. The microchip can use a BlueTooth connection or it can use wired connections. And if the wires are covered by a person's cells like tissue, that protects normal neural tissue or those wires can be put in the cloned blood veins. That thing makes those microchips easier and more comfortable to use. 

Installing those microchips is an easy thing. That implant that is put on the skull can be installed by the daytime surgeon. The installer must only pull tissues away from the skull and put those sensors on the bone. And if the microchip uses the battery the surgeon must drill a hole to the skull and put the battery in the cranial cavity. Or those sensors can be in the plaster. And then put on the skin. The idea is that those sensors are like wireless and fixed EEG-detecting electrodes. 

They can detect how the human brain are acting in real-life situations. That kind of system can use in the next-generation BCI (Brain-Computer Interface). Those systems can use to control the machines and the next-generation jet fighters can use the BCI-user interfaces. 

And there are some futuristic visions that in future the human is turning hybrid with machines. There is the possibility that extremely advanced biotechnology allows the body of the organism to create microchips in its own body. That thing allows those organisms to communicate with machines without borders. But those visions are far away in the future. 

https://scitechdaily.com/biocompatible-innovation-mits-soft-printable-metal-free-electrodes-for-next-gen-implants/