How could the engineering of human tissue be revealed in such detail by a beanstalk? It was for this reason that the research started, taking a different approach outside of DNA, and to confirm this, an independent researcher published a study about, when studying the iPSCs and other pluripotent vegetable cells, decided to completely slice a beanstalk from its roots to its leaves, using a tissue-slicer, shortly after photocopying the cut parts to digitally reassemble and map the internal microfluidics as a template to be used with the artificial tissues. The study, named “Biomimetic and Functioning Artificial Tissues – Mastering Irrigation, Nourishment, Microfluidics and Nerve Networks to Keep the Cells Alive,” exposes research on nerve cell life support that makes up artificial tissues and organs.
With the help of a straightforward beanstalk, it is possible to study life’s fundamental components, learning things that are pertinent to modern medicine and even to the possibility of artificial life.
In addition to the extensive work of mapping the tissues and standardizing the parts, this research aims at collaborative work focused on the nourishment of cells in artificial tissues. It also identifies with code the components of the tissues and processes, for each circulatory and nervous system. The study also demonstrates the potential that emerging fields of knowledge, including nanotopography and biological tissue processes, have for advancing the viability of research into artificial life. Among the subjects and ideas involved in the study, besides the future perspectives to this research contemplate:
• keeping cells alive in tissues by cataloguing vessels, microfluidic components, and minimal process information
• identifying and mapping each circulation microchannel. number linked to a datasheet.
• Create accurate data and information to feed new machines that produce artificial human tissue.
• Generate catalogued information on biological spare-parts with datasheets with full specification and characterization
• Use integrated circuit architecture and complex machine engineering to create microfluidic networks in human tissues.
Future plans call for mapping every human tissue’s microfluidic and bioelectrical flora as well as adding an identification system. number to each irrigation circuit as spare-parts, similar to engineering made in integrated circuit architecture or in mechanics. Each line of circulation flow or communication has been identified by calling its datasheet, which includes all descriptive, technical specification, and characterization to map the cell structures in the artificial tissues, their connections, and the work and processes that they carry out in order to remain alive. As a result, we will have a better understanding of the connections, receptors, and the terminations of nutrition, communication, and fluid transport in a detailed nanotopography.
The goal is to map the nanotopography of biological tissues’ surfaces down to the level of the cellular structure, including its connections, fluid-network matrix, and nerve. A trend that is based on nanotechnology is the creation of biological spare parts for use in artificial organs. In particular, nanotopography will broaden our perspective and reach over the connections and supports that keep cells from living tissues, bringing a clearer focus to the specifics of each cell.
The human body’s components are mapped using nanotechnology and conventional engineering methods, and each part is given a unique identification number. number to call a datasheet presents a huge potential for bringing together and presents understanding of several specialties into one single descriptive manual. In order to have a history, control, and understanding of all the components that make up the whole, a method similar to that used in mechanical engineering is used in the vehicle, complex machinery, helicopter, and aircraft industries.
The creation of new tissues is not the main challenge; instead, methods like using iPSCs induced pluripotent stem cells, but in the organization and functionalization of tissues. The challenge of joining two living cells of a tissue together in a perfect regeneration while maintaining the network of nutrient, electrical, and structural communication is to make this connection visible to the body. We can clearly see the differences between the biosciences’ practical applications and the new sciences’ constrained scope at this stage of science and technology.
However, due to the complexity involved, nanotopography and engineering methods may not be sufficient on their own to create an entirely new tissue mapping technology. Measures are only one aspect of the distinction between nanotechnology and bioscience; there are also effects, events, methods, and processes.
While biology and the biosciences go much further than dimensional, from μm, nm, fragments of particles around angstroms, and moles, nanotechnology operates in the range of 1-100nm. In the case of biosciences, this anthropometry of the biological elements lacks a standard, but we do have some known approximations: biomolecules are between 2 and 16 nm, human cells are between 25 and 100 nm, and measurements of some viruses are close to 150 nm. The body parts are also very diverse. The necessary components of tissues and parasites must be taken into account in this new biological anthropometry involving micro- and nanoparticles. For example, in process engineering, the precise knowledge and uses, effects, events, processes, and energies involved are required in addition to the measurements. Simple but profound research, as there are many cases, particularly in India, that serve as models and are real seeds for great accomplishments, the beginning of great innovations that started in garages, and with the accumulation of knowledge in innovation the breakthrough emerges, and new technologies take shape.
As presented in the recently published study entitled “Biomimetic and Functioning Artificial Tissues – Mastering Irrigation, Nourishment, Microfluidics and Nerve Networks to Keep the Cells Alive”. Future perspectives include the possibility of standardizations as well as more accurate studies with a precise code for identifying biological circuits on all channels of fluid circulation and nutrition. With the help of these studies, the viability of artificial organs will become more precise, and even new organ formats may become common, as is already the case with machine replacement parts. This preliminary study adds more technique as an engineering standardization for this science along with the identification of damaged tissues that need regeneration and a comprehension and number at each termination.
