The classification and listing of human subjectivities [4], revealed the behaviour of logical particle interfaces, e.g., mimicry of biological motor proteins [59] and logical data manipulation [60], [61], [62], presenting tools to be evaluated for evolution in deep tissue engineering. With these technologies, questions arise as to whether human subjectivities can be suppressed entirely from the human body through genetic editing as an advantage to human beings over long distances in space and logical progress, and computer science has advanced virtual human interface controls. The new frontier of these machines is the human emotional intelligence to be programmed in the bio-machines, simulated before in biocircuits [27], including ceramic materials, technologies that can mimic the hypothalamus, [75] and generate computational interfaces and integration, electrical and digital in the brain [51], [52]. With the smoothest interfaces, removing that image of computers as hard hybridized machines with codes without human interactive logic, this one has more user-friendly, differences from that corporate equipment, as the Disney animatronics or human robots for entertainment is the application of robots absorbing the actions and subjectivities of human movements in machines. The mimicry of smooth and delicate movements performed represents parts of the human subjective movement sciences field and their skills. Then mimicking soft elements and smooth movements, in which the robots can express more realistically and represent human subjectivity, absorbed by machines for better communication and interactions with humans, in a perfect communication interface between men and machines. In recent years, with robust, dense fast databases, artificial intelligence, machine interaction with people and even talk biologically at a high level. Indeed, some human subjectivities have a path to be artificially simulated and interact with humans, e.g., virtual robots using human subjectivities. Questions about emotionality or immateriality technologically, through tissue engineering advances, refer to augmented reality interactions with tissues. These techniques could be amplified and connected to the mind to generate accurate interfaces and integration between men and machines, amplifying the synthetic biology that will be in this environment, obtaining benefits and progressing. This evolution is gradually bringing more tools for genetic editing, the Internet of the body (iOB), [4], [66] and these interfaces tend to intensify. This situation will bring DNA better comprehension, control, and suppression, when needed, for synthetic biology [78] and force body human artificialization for logical development because as with most evolution, it is well-developed and well-integrated with the highest product of evolution [2].
11.1 Human body functions and systems mimicked and aided through qubit logic.
Synthesizing and mimicking each functionalized gene in the human body using nanoanalytic instrumentation and allocating them in control blocks to be represented as an engineering flowchart system, amplifying its level controls to identify each gene and particle interaction in the body with an ID number concept [3], to be attached to a datasheet and process it using dense AI is a step advocated in this research. Everything functionalized using control blocks genes to formulate engineering paths and apply its skills to advanced tissue engineering, biotechnology, and genetics, with the objective of formulating a particle control science engineer system, such as CAx to engineers work with genetics and prototype sophisticated functionalized organics soft-hard and functional scaffolds constructions. The human being may have increased biological and physiological capacities and mimicry in all human systems, but for that, it is necessary to catalogue all parts from gene logic to large tissues. The taste, touch, vision, and thermal sensations are added as radar, magnetism, and magnification in the visual and auditory fields, capturing a greater spectrum of light and micro sound. As in mimicry the revascularization electrics and fluidics of the body tissues complemented with gene editing. There are thousands of functions in the human body to be evaluated, and computation can assist it in the physical interface with the particle logic in approximations and mimicked to be recognized by the biological system without rejection [16], [17], [18]. All organic functions are passive for editing to amplify their capabilities through the bioprocess’s logic science to a near interface in control of particles. The global control of large processes linked with complex logics would take place to control particles, specifically in mapping interactions, chemical affinity interfaces and integrations. Each body process was treated as an engineer’s control block and classification package: cardiovascular, respiratory, digestive, nervous, sensory, endocrine, excretory, urinary, reproductive, skeletal, muscular, immune, lymphatic, or integumentary. Following the artificial organs concepts and initiating from the chemical control interface between two particles and their logic to large tissues and the proper prototype construction, i.e., CAx experts engineering processes for high-level genetic molecules manipulators, then try to adapt life in extreme conditions weather of other planets, considering each minimum advantage, at least with more biological resistance.
11.2 Engineering flowchart to calculate and simulate energetic interactions between logic particles
Digitally, it is possible to use an engineering flowchart to condense the gene particle mechanism processes parts and their energetic events, connections, and physical-chemical communications, focusing on their particle interactions and even physics. Then, making use of the human genome project in a step further, cutting-edge technologies for more practical engineering procedures design usage and standards, so that human bodies come to be seen and treated almost as a machine, due to the high precision of analysed synthetic biology. The most intense use of particle mapping and activator genes [15], is complemented with modern genetic editing with an analytical mechanical engineering process. There are no limits to optimizing the complete nanomapping tissues to help identify gene controls, [44]. With a focus on the mechanical interactions between particles in the dynamism interfaces on complex chemical interactions with these processes, map and artificially simulate them, e.g., cell-on-a-chip and bioreactors [22], [35], complementing the advanced studies in genetics, biotechnology, and genes edition with computation and mechanical precision, electrical and chemical engineering standards. The technology cell-on-a-chip concepts consider as start analytical procedures, identifying a specific event gene stretch, then reading its gene transcription and digitalizing it to sketch an engineering flowcharts and diagrams for artificial simulation specific gene event, all monitored with quantum computer control for the properly analytical results study. With these technologies and modern engineering techniques, fluid mechanics are at a below level in nanomanufacturing processes. With replicable methods in assembly blocks to synthesize the cell. From an engineering point of view added, focusing on nanomanufacturing, and basic procedures, which along this route include:
• First map and simulate the gene mechanism digitally, inserting an ID number for each particle and its processes, to an interface in the digital connection in vitro, performing each local chemical synthesis to map its global interactions and map them by the physical-chemical interactions of strong and weak bonds between gene particles.
• Second is generating a complex and complete microbioreactors, logic particles, logic valves and flow automation in interface with AI aided by engineering, [42]. For each gene stretch, their mapped characteristics and logic interaction particles, generate datasheets of understood structures to mimic complex or simple functions and events.