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The Nanotechnology for Mapping and Cataloguing With I.D. Number the Human Tissues Parts As Machines
How can the beanstalk tell us so much about human tissue engineering? For this reason, research began, taking an alternative route beyond DNA, and to verify this, an independent researcher published a study about the decision to cut the leaves of a beanstalk completely from its root when studying iPSCs and other pluripotent vegetable cells. , using a tissue-slicer, map cut sections as templates for applying internal microfluidics to artificial tissues by digitally reassembling them immediately after photocopying. The study, titled “Biomimetic and Functioning Artificial Tissues – Mastering Irrigation, Nutrition, Microfluidics and Nerve Networks to Keep the Cell Alive,” reveals research on the life support of nerve cells that make up artificial tissues and organs.
Through a simple beanstalk the essence of life can be studied at its heart, bringing relevant information to modern medicine and also to the possible understanding of the potential of artificial life.
In addition to tissue mapping and quantification of parts, for each circulatory and nervous system, the research aims for collaborative work focused on cell nutrition in artificial tissues. The study also shows the potential of new science and technology to provide the feasibility of new studies for artificial life, which is related to the greater precision of the overall understanding of biological tissue processes at the nanotopographic level. In addition to the future perspective of this research reflection, the topics and ideas covered in the study:
• Minimal process data for cataloging vessels and microfluidic compartments and keeping cells alive in tissues.
• Mapping and code of each circulating microchannel with a code ID number linked to the datasheet.
• Generate accurate data and information to feed new human synthetic tissue production machines.
• Generate cataloged information on biological spare-parts with datasheets with complete specifications and specifications
• Use traditional engineering techniques of complex machines and integrated circuit architectures for microfluidic networks in human tissues.
A future aim is to map the entire microfluidic and bioelectrical flora of human tissues and add an ID number to each irrigation circuit as spare-parts, similar to those engineered in integrated circuit architecture or mechanics. Each circulation flow or line of communication calls for its datasheet with all descriptive, technical details and specifications mapping the cell structure, their connections, function and the process they undergo to survive in the artificial tissue. With this, we will better understand the connections, receptors and their termination of nutrition, communication and transport of fluids in detailed nanotopography.
The idea is to map nanotopography on the surface of biological tissue at the level of cellular structure, including its matrix of connections, fluid and neural networks. The creation of biological spare parts for use in prostheses is a trend that is based on nanotechnology, especially through nanotopography that will expand our vision and reach contacts and support the separation of cells from living tissues, which will provide a clear focus on details. each cell.
Nanotechnology and techniques used in traditional engineering for mapping components of the human body and documenting parts with ID numbers to call datasheets have tremendous potential to bring together and present an understanding of multiple features in a single descriptive manual. Having the history, control and knowledge of all the parts that make up a whole similar to the techniques used in mechanical engineering used in the aircraft, helicopter, vehicle and complex machinery industries.
The main difficulty is not in the formation of new tissue, e.g. Using iPSCs induced pluripotent stem cells, but in tissue organization and functionality. In repairing two living cells of a tissue, the problem is to reattach them, maintain the network of complete regeneration, nutrition, electrical and structural communication intact, as well as recognition of this connection by the body. At this border of science and technology we can clearly see the difference between the practical applications of bioscience and the limited scope of the new sciences.
However, nanotopography and engineering techniques alone will not be sufficient for a complete new tissue mapping technology, due to the complexities involved. The difference surrounding nanotechnology and bioscience is defined not only by solutions but also by effects, phenomena, methods and processes.
While nanotechnology operates in the 1-100nm range, biology and biosciences go far beyond dimensionality, passing through particle fragments around μm, nm, angstroms and moles. In the case of biology, this anthropology of biological entities does not have a standard, but we have some known approximations, biomolecules are between 2-16nm, human cells are in 25-100μm, in addition to the measurement of some viruses near 150nm, the organs of the body are very diverse. In this new biological anthropology involving micro/nanoparticles, essential tissue components and parasites must be considered. In general, a complete set is required in addition to measurements, as in process engineering, which includes accurate knowledge and applications, effects, phenomena, processes and energy. Such a simple but profound research, because there are many cases in India which are particularly exemplary and which are the true seeds of great achievements, the origins of great innovations that start in garages, and progress with the accumulation of innovative knowledge, and new technologies are developed. shape
As presented in the recently published study “Biomimetic and Functioning Artificial Tissues – Mastering Irrigation, Nourishment, Microfluidics and Nerve Networks to Keep the Cell Alive”. Future approaches with accurate codes for the identification of biological circuits across all fluid circulation and nutrition channels will be feasible, making more precise studies and even standardization possible. These studies will make the feasibility of artificial limbs increasingly precise, and the appearance of new limbs may become commonplace, as has already been done with replacement parts of the machine. As well as the identification of damaged tissues that require regeneration with understanding and quantification at each end point, this preliminary study brings more techniques as engineering standardization to this science.
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