Nanotechnology- it is the technique of engineering matter at an atomic level. This technology is quite different from any other ever witnessed before. To justify how difference this technique is, the way to attaining different compound that human beings have practiced for centuries involves mixing quantities of different compounds to produce one compound containing elements of all the mixed compounds, but exhibiting different features.
This is what formidable scientists call innovation. Nevertheless, not anymore, this kind of innovation is intriguing because from one atom, creating several other atoms with unique structures is possible (Freitas 1-3).
In agriculture, the use of nanotechnology in genetic engineering to attain maximum food production has surpassed the local agricultural methods. In addition, it is considered as its exact opposite. People consume the GMOs without any knowledge of their negative effects like severe death of human cell, brain cells and cancerous effects. Locally produced food result in none of the mentioned effects, in fact, they are safe for consumption. This justifies that nanotechnology is different (Freitas 1-3).
The structure of nanorobots and body cell – the body cell has a nucleus that is considered as the largest organelle. Due to its size, it is able to accommodate a medical nanorobot. Its structure is made of nucleolus that is encompassed by a nuclear membrane and its location is in the cytoplasm. The main function of a nuclear is the storage of genetic data of a person.
Nanorobots are assumed to have the take the rectangular or circular shapes for the purpose of studies. Its volume is 69.250 micron3, surface area of 102.778 micron2, a mass of 80.239pg when dry, width measuring 4.18 microns, a height of 3.28 microns and a length of 5.05 microns. Bloodstream nanorobots are designed to be capable of floating and have a limited trans-device diameter to allow free passage through even the smallest capillary vessels in human beings (Freitas 15-25).
Using nanorobots to repair cells- The nanorobots are designed both internally and externally to suit their purpose. It has a section called proboscis manipulator, sensors, vaults and receivers with different functions. The proboscis is a large manipulator with an axial position designed to extract existing chromatin in the nucleus. After a while, the nanorobot replaces the old chromatin by introducing a new dose from within itself into the nucleus through a mechanism called conduit flow.
This is the mechanism used by nanorobots to repair cells, by emptying nucleus and refilling a new dose of chromatin inside the emptied nucleus after a while. The chromatin being discharged into the cell is stored in a section of the nanorobot called the vault. Chromatin that has been sucked out the nucleus is also stored in the other vault (Freitas 25-30).
Strategy of cell repairing- to obtain the chromatin set that is to be replaced, a new set must be manufactured by first obtaining the structure of the old chromatin using ex vivo, an equipment that reads the DNA structures. The complete DNA structure is thereafter passed to a manufacturing equipment to produce chromatin and store them inside the chromallocyte (nanorobot).
The process begins with obtaining randomly selected samples of DNA from various human organs through a genome CRT procedure. One of the methods for DNA samples involve using chromallocyte nanorobots specifically designed to obtain the DNA without any rupture. After obtaining the samples, they test for viability and the most viable DNA sample structure is manufactured through the above-mentioned process (Freitas 40-49).
Benefits of cell repairing by nanorobots- as it has been explained in the above contexts, the purpose of Nanomedicine is to create more efficient and blameless cells in the sense that all unwanted components of the initial cell are removed using nanorobots. Using this concept, chromosomes containing pathogens like cancer and other genetically inherited anomalies can be removed out of a DNA structure. Therefore, the benefit of this technique is disease prevention at the DNA structure level (Freitas 45-50).
A side effect of cell repairing nanorobots- it is indicated that cell engineering has grave effects on human beings. Most of the food products consumed by humans contain nanosilver. This component is said to be highly toxic and could result in various cancerous diseases. From an environmental point of view, nanosilver is toxic to nitrifying bacteria. Detergents contain this compound and its introduction to the environment in the form of water disposal poses a devastating environmental risk (Higgs 1-3).
Works Cited
Freitas, Robert A “The Ideal Gene Delivery Vector: Chromallocytes, Cell repair Nanorobots for Chromosome Replacement Therapy”. Journal of Evolution and Technology. 16. 1 (2007): 1-97. Web.
Higgs, Steven 2009, Mama, Dada, and Nano? Sub-particles May Be Toxic for Kids. 2013. Web.