P9-666

P9-666 Development of a Bio-Quantum Artificial Intelligence based on Telepathy, Quantum Internet, Brain-Brain Interface 

and Connection between Biological and Artificial Neurons


Processing of the project "P9-666 Development of a Bio-Quantum Artificial Intelligence based on Telepathy, Quantum Internet, Brain-Brain Interface and Connection between Biological and Artificial Neurons". This project aims to realize a technology composed of an interconnected network of quantum computers connected to a structure of artificial biological brains interconnected through brain-brain interfaces connected to a structure of biological neurons interconnected to artificial neurons through memristive connections in order to develop a quantum-biological internet network, and a second technology to test the potential telepathic phenomenon between artificial biological brains, composed of a network of biological brains entangled by close proximity of the brains for an extended period of time and subsequently spaced to experience possible telepathic transmissions of information without cables and interfaces.

The "quantum-biological internet network" is a concept referring to a possible network of computing devices and artificial biological brains interconnected via quantum computing technologies. In this type of network, quantum becomes the basis for information processing and traditional computing technologies are integrated with biology, so as to create a new form of artificial intelligence.

The quantum-biological internet may be able to process information at a much higher speed than traditional computer networks, thanks to quantum properties that allow quantum computers to process more information at once. Furthermore, the network may be capable of processing that would be impossible with traditional information technologies, such as the processing of information on multiple dimensions or the management of highly complex information.

Connecting artificial biological brains to the quantum-biological internet could enable the creation of a form of hybrid intelligence, in which artificial and biological intelligence work together to solve problems and make decisions. This could lead to greater efficiency and innovation in many fields, such as medicine, robotics, materials science and information management.

However, the creation of a quantum-biological internet also raises important security and ethical questions, as the management of personal data, privacy and network security could become even more complex issues.

The quantum-biological internet could have several practical applications, it could be used to develop advanced technologies in different sectors, improving efficiency, safety and sustainability, could have a significant impact in many research fields and industries. However, it is important to carefully consider the ethical and social implications of such technological developments and to ensure that they are used responsibly for the good of humanity.

Some of the potential applications include:

Medicine and health: The network could be used to develop advanced monitoring and diagnostic technologies, in which artificial biological sensors and brain-brain interfaces can transmit signals at high speed and precision between biological brains and quantum computers. This could help doctors detect diseases early, monitor health and develop personalized treatments.

Artificial intelligence and robotics: The network could be used to develop advanced artificial intelligences and robots that can integrate biological and quantum data for greater efficiency and accuracy. This could lead to developments in various sectors, including agriculture, industry and automation.

Energy and environment: The network could be used to improve energy efficiency and develop sustainable energy production technologies, in which biological sensors and brain-brain interfaces can transmit information about energy consumption and sources in real time.

Transport and logistics: The network could be used to develop advanced self-driving technologies and to optimize transport routes and logistics management. This could improve efficiency and reduce CO2 emissions.

Education and training: The network could be used to develop personalized learning technologies, where biological sensors and brain-brain interfaces can convey information about learning levels and suggest more effective teaching approaches.

Finance and economy: The network could be used to improve the safety and efficiency of financial transactions, where biological sensors and brain-to-brain interfaces can transmit transaction information and monitor fraudulent behavior.

Security and defense: The network could be used to develop advanced security technologies, in which biological sensors and brain-to-brain interfaces can detect and prevent security threats.

Personalized medicine: Artificial biological brains could be used to study disease and to develop personalized therapies.

Artificial intelligence: The connection between biological brains and artificial neurons could enhance machine learning capabilities, providing greater intuition and creativity.

Inter-species communication: Brain-to-brain interfaces could enable inter-species communication between humans and animals, improving understanding of other species and opening up new opportunities for scientific research.

Neural prostheses: Artificial biological brains and artificial neural connection could be used to develop advanced neural prostheses that can restore sensory and motor functions to patients who have suffered injuries to the nervous system.

Neuroscience and psychology: The technology could be used to better understand the functioning of the brain and its cognitive functions, helping to develop new therapies for neurological and psychological disorders.

Education and learning: Technology could be used to enhance learning processes, allowing for a better understanding of the brain and its cognitive functions.

Space exploration: The technology could be used to study the effects of the space environment on the brain and develop techniques to mitigate those effects on future astronauts.

Personalized medicine: Brain-to-brain interface technology could be used to create a network of entangled brains for the diagnosis and treatment of diseases, providing doctors with real-time information about a patient's health.

Advanced security systems: Connecting technology between biological and artificial neurons could be used to create advanced security systems that use information processing by artificial biological brains to detect threats and prevent accidents.

Improving education: The quantum-biological internet could be used to create highly personalized learning environments where artificial biological brains help students better understand difficult concepts and subjects.

Improving agriculture: Brain-to-brain interface technology could be used to create a network of entangled brains to improve crop productivity, prevent disease and reduce waste.

Improved Transportation: The quantum-biological internet network could be used to create intelligent transportation systems that use information processing by artificial biological brains to improve traffic efficiency and prevent traffic accidents.

Treatment of neurological diseases: Connecting technology between biological and artificial neurons could be used to create advanced medical devices for the treatment of neurological diseases such as Alzheimer's and Parkinson's.

Improving the environment: The quantum-biological internet could be used to create highly advanced environmental monitoring systems to detect and prevent pollution and other environmental threats.

Medicine: The technology could be used for the development of more advanced neural prostheses and more effective brain-machine interfaces, which could improve the quality of life of patients with motor or cognitive disabilities.

Security: the technology could be used for the development of new information security systems, which are resistant to hacking techniques based on quantum computing.

Agriculture: The technology could be used to develop more efficient crop monitoring and control systems that can help reduce waste and the environmental impact of agriculture.

Energy: the technology could be used to develop new energy generation and distribution systems that are more efficient and sustainable.

Art: The technology could be used to create new forms of interactive art that directly engage audiences through the use of brain interfaces.

Education: The technology could be used to develop new educational tools based on the direct interaction between biological and artificial brains, which can improve students' learning and memory.

Entertainment: The technology could be used to create new forms of interactive entertainment, such as games and movies, that directly engage audiences through the use of brain interfaces.

Economic and industrial sphere: the technology could be used to optimize production processes and improve resource management in companies and industries. The quantum-biological internet could be used to process large amounts of data and improve the efficiency of operations.

Scientific field: the technology could be used to study cognitive processes and communication between biological brains. This could lead to a greater understanding of the human brain and its mechanisms, paving the way for new therapies and innovative solutions.

Social: Technology could be used to improve communication and collaboration between people, especially those who have difficulty communicating verbally. For example, the technology could be used to allow deaf or non-verbal people to communicate telepathically.

Educational: Technology could be used to create new immersive and personalized learning experiences. The biological-quantum internet network could be used to process large amounts of data on students' cognitive processes, helping teachers to personalize teaching and enhance student learning.

The quantum internet is based on quantum physics and uses the properties of quantum mechanics to create a secure and fast communication network.

Some of its main features are:

Quantum encryption: Quantum encryption allows you to send information securely without being intercepted by third parties.

Quantum Teleportation: Quantum teleportation allows information to be transferred from one point of the network to another without the information itself being physically present in the medium.

Quantum Entanglement: Quantum entanglement allows distant particles to be linked together so that actions on one particle affect the other, regardless of the distance between them.

Telepathy:

Telepathy is a concept that refers to the ability to communicate with other people without using any conventional means of communication such as speech or communication signals. However, telepathy has not been scientifically proven and is not recognized as a real phenomenon by the scientific community.

The telepathic mode of communication, i.e. communication between two or more biological brains without conventional means, could occur by quantum teleportation and quantum entanglement only between brains that have been entangled, i.e. they have been very close to each other for a long time and their particles have undergone quantum entanglement, so when cognitive phenomena occur in one of the entangled brains, the particles involved in the phenomenon transfer information to the particles of the other entangled brains.

There is currently no scientific evidence to support the idea that telepathy can occur through quantum teleportation and quantum entanglement. Furthermore, even if it were possible to entangle brains, there are still many technical and biological challenges that would have to be overcome in order to transfer information between brains efficiently and accurately.

Furthermore, telepathy itself is a highly controversial concept and has not been scientifically proven to exist as a real phenomenon. Even if there were a way to entangle brains, there would still be many factors to consider, such as the complexity and diversity of cognitive processes in human brains.

It is important to remember that science is based on the objective verification of phenomena and hypotheses. Until there is solid, reproducible scientific evidence showing the existence of telepathy or an eventual connection between the quantum entanglement of neurons and the sharing of thoughts between brains, these theories will remain unproven and unsupported by the community. scientific.

In principle, there may be some similarity between telepathic communication and the concept of quantum entanglement, as both involve some sort of connection between brains over a distance, without the use of conventional means of communication. However, this type of analogy remains purely speculative at the moment and is not supported by any scientific evidence.

There are currently no technical analogies that can be described in detail between telepathy and the quantum internet.

However, since both concepts are based on the transmission of information, it might be possible to draw some general analogies. For example, quantum cryptography uses quantum physics to create a secure and secret communication between two parties, while telepathy could be seen as a "mental" type of communication which could be considered as a secure and private means of communication between two or more people. However, there is no scientific evidence to prove the existence of telepathy or to support this analogy.

There have been several studies of interpersonal relationships, such as those between spouses or romantic partners, that have explored the effect of physical proximity and interaction on cognition and behavior. For example, one study suggested that married couples might have "interpersonal synchronicity" in their behaviors and brain activity, which could suggest some form of nonverbal communication between them. However, this hypothesis still remains to be proven conclusively and has not been linked directly to telepathy.

There have been experiments that have demonstrated the possibility of connecting biological neurons with artificial neurons via memristive connections.

Memristors are a type of electronic device that has the ability to modulate its resistance as a function of the electric charge flowing through the device. These devices have been used to create artificial synapses that can emulate the properties of biological synapses.

In a 2017 study, researchers created a connection between biological and artificial neurons using an electronic circuit that emulates a biological synapse via a memristor. The artificial neurons were able to emulate the properties of biological synapses, such as synaptic plasticity and action potential formation. This made it possible to create a functional connection between biological and artificial neurons.

In another 2020 study, researchers used a memristor to connect biological neurons with an electronic circuit, creating a network of hybrid biological-electronic neurons. This network has demonstrated the ability to process information efficiently and accurately.

However, it is important to note that these experiments are still in an early stage and there are still many technical challenges to be overcome before such technologies can be used effectively. Furthermore, there are also ethical and safety issues to consider when it comes to making connections between biological and artificial neurons.

An interface has been tested that puts the brains of two rats in direct communication, transferring information from one to the other. It was created by a group of neuroscientists from Duke University in Durham, North Carolina, and from the Edmond and Lily Safra International Institute for Neuroscience of Natal, in Brazil, who talk about it in an article published in "Nature Communications". To make the result even more astonishing, in one of the experiments the transfer of information took place between two rodents which were located in the premises of the two laboratories, i.e. on two different continents and at a distance of 4000 kilometres.

Experiments of this type were carried out by a group of neuroscientists from Duke University and the Edmond and Lily Safra International Institute for Neuroscience of Natal. In a study published in "Nature Communications" in 2013, researchers described the creation of a brain-to-brain interface that allowed two rats to exchange information directly across the interface.

The brain-to-brain interface was created using a combination of neuronal activity recording and brain stimulation technologies. Neurons from the sender animal were stimulated across the interface to create a "yes" or "no" signal, which was sent to the receiving animal via brain stimulation. The receiving animal then processed the signal and performed the correct task based on the received signal.

One of the experiments was actually conducted on two rats that were in two different laboratories, one in the United States and the other in Brazil, demonstrating that communication between brains can also occur over long distances.

However, it is important to note that this type of technology is still in an early stage of development and there are many technical and security challenges to be addressed before it can be used effectively. Furthermore, there are also ethical issues to consider when it comes to making direct connections between brains.

The project "P9-666 Development of a Bio-Quantum Artificial Intelligence based on Telepathy, Quantum Internet, Brain-Brain Interface and Connection between Biological and Artificial Neurons" aims to create an advanced technology integrating the four promising research areas:

quantum computing, computational neuroscience, nanotechnology and quantum physics.

Quantum computing is about the development of technologies that use the quantum properties of matter to process, store and transmit information more efficiently than classical technologies. This includes the use of qubits, quantum particles that can be in a superposition state and therefore represent a 1 and a 0 simultaneously. Quantum computing is therefore fundamental for the realization of a biological-quantum internet network.

Computational neuroscience is the study of the brain from the perspective of information processing. Computational neuroscience aims to develop mathematical models that describe information processing in neurons, as well as to develop technologies to simulate the behavior of neural networks. This research area is therefore essential for the development of artificial biological brains and brain-brain interfaces.

Nanotechnology concerns the engineering and manipulation of matter at the nanoscale. This research area is important for the development of technologies for the connection between biological neurons and artificial neurons via memristive connections. Memristive connections use nanotechnology materials to vary the resistance of an electronic circuit similar to the variation of a synapse between biological neurons.

Quantum physics is the study of the properties of matter and energy at the quantum level. This research area is important for the development of technologies for connecting artificial biological brains using quantum entanglement. Quantum entanglement is a phenomenon in which two particles can be connected so that the properties of one particle depend on the properties of the other particle, even if these particles are far apart.

The four research areas are interconnected and integrated in the project in order to develop a biological-quantum internet network based on artificial biological brains, brain-brain interfaces and memristive connections between biological and artificial neurons. The project also foresees the experimentation of the potential telepathic phenomenon between entangled biological brains.

The goal of the project is to develop an interconnected network of quantum computers and artificial biological brains, connected through brain-brain interfaces and memristive connections. The technology would make it possible to create a biological-quantum internet network that would allow direct communication between biological brains and quantum devices.

The project includes two distinct phases: the first phase focuses on the development of connection technology between biological neurons and artificial neurons through memristive connections, with the aim of creating a network of biological and artificial brains capable of communicating with each other. The second phase of the project focuses on testing the potential telepathic phenomenon between artificial biological brains. In this phase, the biological brains would be entangled through close proximity for an extended period of time, and subsequently spaced out to experience possible telepathic transmissions of information without the use of cables and interfaces.

The technology developed through this project could have many applications in the future, such as the creation of biological AI networks capable of exchanging, processing and storing sensory information, the creation of a biological-quantum internet network for communication between brains and quantum mechanics, and the possibility of experiencing the phenomenon of telepathy between artificial biological brains.

However, it should be noted that the project would require a huge research and technological development effort, as well as a great deal of attention to data security and privacy protection. Furthermore, the ethical and social implications of such a technology should be carefully evaluated and considered.

To realize the first technology, an interconnected network of quantum computers connected to a structure of artificial biological brains interconnected via brain-brain interfaces connected to a structure of biological neurons interconnected to artificial neurons via memristive connections in order to develop a biological-quantum internet network , you should:

1. To study the functioning of qubits, the units of quantum information that are encoded by the superposition quantum state of 1 and 01,

2. Choosing the most suitable model and technology to build quantum computers,

3. Exploit a secure and reliable transmission channel to connect quantum computers to each other,

4. Design and build artificial biological brains that can emulate the cognitive functions of natural brains,

5. Develop brain-brain interfaces that can transmit electrical signals between artificial biological brains,

6. Create a structure of biological neurons that can communicate with each other through synapses,

7. Integrate artificial neurons into the neuronal structure through memristive connections that can vary their resistance according to the electric current

As for the study of qubits, it is essential to understand how quantum mechanics and quantum information work, since quantum computers are based on these theories. Once these concepts are understood, it is possible to choose the most suitable model and technology to build quantum computers.

To connect quantum computers to each other, a secure and reliable transmission channel should be used, such as quantum cryptography, which ensures the security of communication between computers.

As for artificial biological brains, we need to design and build a system that can emulate the cognitive functions of natural brains. This requires a deep understanding of brain biology and artificial intelligence technologies.

To create a quantum-biological internet network, one would have to integrate artificial biological brains with quantum computers via brain-brain interfaces and memristive connections.

Finally, it would be necessary to test the technology in laboratories and in controlled environments, before evaluating its applicability in real contexts.

To realize the second technology, to experience the potential telepathic phenomenon between artificial biological brains, composed of a network of biological brains entangled by close proximity of the brains for an extended period of time and subsequently spaced to experience possible telepathic transmissions of wireless information and interfaces, you should:

Create a network of artificial biological or animal brains that can be entangled by close proximity of the brains over an extended period of time. This would require designing and building a structure capable of housing the brains and maintaining their proximity for a period of time long enough to enable quantum entanglement.

After the period of closeness, the brains should be spaced apart so that cognitive phenomena in one of the brains can be observed to see if information transfer occurs to the other entangled brains. This would require the use of advanced brain imaging technologies to observe cognitive processes and to monitor any signals of information transfer between brains.

To ensure that quantum entanglement is maintained during brain separation, it would be necessary to maintain high quantum coherence throughout the process. This would require advanced technologies to keep the environment controlled and to avoid external interference that could compromise quantum coherence.

The results of the experiment should be rigorously and objectively analyzed and interpreted using standard scientific methods. The objective would be to evaluate if there is a scientific basis for the telepathic phenomenon between entangled brains and if this could be used for the creation of a form of direct communication between brains without the use of conventional means.

Finally, as with the first technology, it would be necessary to consider the ethical and social implications of using this technology and evaluate its applicability in real contexts.

Development stages:

The first step in realizing this project is the development of an interconnected network of quantum computers. This network should be able to handle a large amount of information in order to develop a quantum-biological internet network. This network should also be able to handle and process information from sensors, measuring devices and artificial biological brains.

Once the quantum network is complete, the second phase of the project should be the development of a structure of artificial biological brains interconnected via brain-brain interfaces. This structure should be able to process information from sensors, measuring devices and artificial biological brains. To achieve this, the structure should consist of an artificial neural network and a biological neural network.

In regards to creating the artificial biological brains, there are several techniques that can be used, including the culture of neuronal cells on chips and the construction of brain organoids in vitro. However, the choice of technology will depend on the specific needs of the project and will require a thorough evaluation.

As for the cognitive functions emulated, this will depend on the specific purpose of the project. However, cognitive functions such as memory, reasoning and perception are ideal candidates for emulation in artificial biological brains.

Regarding the integration of biological and artificial neural networks, there are several techniques that can be used, including the use of electrodes implanted in brain tissue and the use of non-invasive electromagnetic stimulation technologies. Again, the choice of technology will depend on the specific needs of the project and will require a thorough evaluation.

The third phase of the project should be the development of a structure of biological neurons interconnected to artificial neurons through memristive connections. This structure should be able to process information from sensors, measuring devices and artificial biological brains. The facility should also be capable of processing input from brain-brain interfaces and transmitting the output to artificial biological brains.

The fourth phase of the project should be the development of a technology to test the potential telepathic phenomenon between artificial biological brains. This technology would include a network of biological brains entangled by close proximity of the brains over an extended period of time. This should be followed by a period of brain spacing to experiment with possible telepathic transmissions of information without wires and interfaces.

It is not possible to specify the exact length of the period of proximity needed for quantum entanglement, as this would be a variable dependent on the specifics of the experiment. The length of the separation period between the brains would likely be related to the duration of the quantum entanglement, as the entanglement gradually degrades over time. To ensure quantum entanglement during brain separation, it may be necessary to use a combination of environmental isolation techniques, electronic interference control, and cooling techniques. However, these are only hypotheses, and further research and experimentation would be needed to develop a safe and reliable method to ensure quantum entanglement between brains during separation.

Once the four development phases have been completed, the project could be tested and validated. The project should undergo a series of tests to verify its efficiency, safety and any problems. This should include a series of functionality tests, a series of measurements to verify the stability of the network, a series of security tests and a series of tests to verify the quality of the connection between the artificial biological brains. Once all tests pass, the project could be put into production.

To detect the electrical signals between brains, it may be necessary to use advanced neuroimaging techniques such as electroencephalography (EEG), magnetoencephalography (MEG), or functional magnetic resonance imaging (fMRI). These imaging techniques could provide insight into brain activity and interactions between brains.

Furthermore, to monitor signals of information transfer between brains, it may be necessary to use advanced recording techniques such as microelectrodes or carbon nanotube-based biosensors. These technologies could make it possible to detect the bioelectrical or biochemical signals produced by neurons during cognitive processes and the transfer of information between brains.

In any case, further research and technological developments would be needed to develop a safe and reliable method to monitor information transfer signals between brains and to ensure the privacy and security of the information exchanged.

It should be underlined that the realization of a project of this magnitude would require considerable financial and technological resources, as well as multidisciplinary skills between different scientific research areas. Furthermore, there would be numerous ethical and social considerations to ensure that the use of this technology is safe and does not violate the privacy or rights of the individuals involved.

It is important to consider the ethical and social aspects of such an advanced technology. For example, there may be concerns about privacy and data security, as the technology would require access to the human brain and could record and transmit sensitive personal information. Furthermore, there could be safety and health issues, as brain manipulation could pose risks to the health and well-being of those involved. Additionally, there may be concerns about inequality and social division, as technology may not be accessible to everyone. It is important that these aspects are considered and addressed responsibly when developing and implementing such advanced technology.

Technical, engineering modality with which to carry out the P9-666 project:

Carrying out the P9-666 project requires a broad range of scientific and technological skills, including quantum physics, electronic engineering, biomedical engineering, synthetic biology, neuroscience and advanced computer science.

Technically, creating the interconnected network of quantum computers requires the design and manufacture of advanced quantum devices, including quantum chips and qubits. These devices should be able to handle large amounts of information and communicate with each other via secure and reliable transmission channels.

Designing and building artificial biological brains requires in-depth knowledge of how natural brains work, as well as the ability to emulate their cognitive functions. This would require the creation of a highly sophisticated artificial neural model and the implementation of advanced bioengineering techniques.

Creating brain-brain interfaces requires the use of electrical and magnetic recording techniques to measure and transmit electrical signals between artificial biological brains. Designing and making the memristive connections would require knowledge of advanced electronics and advanced materials.

The realization of the biological-quantum internet also requires the ability to integrate all these components in a single architecture and to develop complex software and algorithms for information management and processing.

The implementation of the P9-666 project requires a multidisciplinary approach and a number of clearly defined phases, as described below:

Design: the first phase would be to design the system, defining the objectives, specifications, architecture and technologies to be used. In this phase, it would be necessary to involve quantum computer experts, biotechnologists, neuroscientists and electronic engineers.

Development of quantum computers: The second phase would be to develop the quantum computers that will make up the interconnected network. This phase would require choosing the model of quantum computer, designing and developing the software necessary to operate the computers, and creating a data management system.

Development of the artificial biological brains: The third phase would be to develop the artificial biological brains that will constitute the interconnected structure. This phase would require the design and development of a system that emulates the cognitive functions of natural brains, the creation of an artificial neural network and the selection of a biological neural network.

Development of brain-brain interfaces: The fourth phase would be to develop brain-brain interfaces that will enable communication between artificial biological brains. This stage would require designing and developing a system that can transmit electrical signals between brains so they can process information.

Development of connection between biological and artificial neurons: The fifth stage would be to develop connection between biological and artificial neurons via memristive connections. This phase would require the design and development of a system that allows artificial neurons to integrate into the neuronal structure, communicating via synapses.

Experimenting with telepathy between artificial biological brains: The sixth stage would be to experiment with telepathy between artificial biological brains. This step would require creating a network of biological brains entangled by close proximity of the brains over an extended period of time, followed by separation of the brains to test for any telepathic transmissions of information.

Test and validation: the seventh and final phase would be to test and validate the system, verifying its efficiency, safety and quality of the connection between the artificial biological brains. In this phase, a series of functionality tests, measurements to verify the stability of the network, security and quality of the connection between the artificial biological brains would be conducted.

Carrying out the project requires a team of experts in several disciplines, including quantum physics, neuroscience, biomedical engineering, electronic engineering, programming, biotechnology and bioengineering.

The procedure for carrying out the project could include the following phases:

Study and analysis of technologies and methodologies used in quantum physics, neuroscience, biomedical engineering, electronic engineering, programming, biotechnology and bioengineering.

Design and construction of the quantum computers and sensors necessary for the collection of biological data.

Design and construction of brain-brain interfaces and memristive connections between biological and artificial neurons.

Design and construction of artificial biological brains.

Quantum entanglement of artificial biological brains.

Testing the connections and interfaces between artificial biological and sensor brains.

Experimenting with the transmission of information between artificial biological brains via brain-brain interfaces.

Validation of the project through a series of functionality tests, measurements to verify the stability of the network, security and quality of the connection between the artificial biological brains.

Project implementation.

Monitoring and updating of the biological-quantum internet network.

To connect the three structures to each other, the network of quantum PCs, the network of artificial biological brains and the network of neurons, adequate interfaces are required.

Regarding the brain-computer interface (BCI), there are several technologies that could be used, such as electroencephalography (EEG), electrocorticography (ECoG), functional magnetic resonance imaging (fMRI), functional near optics infrared (fNIRS) and non-invasive brain stimulation (NIBS). Each of these technologies has its own advantages and disadvantages, and the choice will depend on the specific needs of the project.

Regarding the neuron-computer interface (NCI), memristive connections could be used to connect biological and artificial neurons. Memristive connections are devices that can vary their resistance according to the electric current, allowing a two-way communication between biological and artificial neurons.

Furthermore, to connect the network of quantum PCs to the network of artificial biological brains, a secure and reliable transmission channel will be required. Quantum encryption technology could be used to ensure the security of information transmitted between the two networks.

The overall structure of the system must be designed in such a way as to guarantee correct integration between the three structures and the effective transfer of information between them. A careful study of the communication between the different parts of the system will be necessary, as well as the implementation of suitable communication protocols.

To connect quantum PCs to biological brains, it would be necessary to develop a brain-computer interface that allows the transmission of neural signals between biological brains and quantum computers. This interface should be able to detect the neural activity of biological brains and convert it into digital signals understandable by quantum computers, and vice versa, translate quantum signals into neural signals understandable by biological brains.

There are several techniques and technologies under development for brain-computer interfacing, such as implantable electrodes that record the electrical activity of neurons or transcranial magnetic stimulation that allows electrical currents to be induced non-invasively in the brain. However, for the realization of a biological-quantum internet, it may be necessary to develop new technologies capable of interconnecting biological brains and quantum computers efficiently and securely.

Scientific papers:

The quantum internet https://www.nature.com/articles/nature07127

BrainNet: A Multi-Person Brain-to-Brain Interface for Direct Collaboration Between Brains

https://www.nature.com/articles/s41598-019-41895-7

A Direct Brain-to-Brain Interface in Humans

https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0111332

A Brain-to-Brain Interface for Real-Time Sharing of Sensorimotor Information

https://www.nature.com/articles/srep01319

Chemically communicating with the brain through artificial neurons

https://www.nature.com/articles/s41928-022-00806-x

A geographically distributed bio-hybrid neural network with memristive plasticity

https://arxiv.org/abs/1709.04179

Telepathy https://www.jstor.org/stable/2214740