Abstract
Since the 1980s, molecular biology has been used to investigate medical field mechanisms that still require the use of crude biological materials in order to achieve their necessary goals. Transcription factor-induced pluripotent stem cells are used in regenerative medicine to screen drugs and to support lost tissues. However, these cells insufficiently reconstruct whole organs and require various intact cells, such as damaged livers and diabetic pancreases. For efficient gene transfer in medical use, virally mediated gene transfers are used, although immunogenic issues are investigated. To obtain efficient detective and diagnostic power in intractable diseases, biological tools such as roundworms and zebrafish have been found to be useful for high-throughput screening (HST) and diagnosis. Taken together, this biological approach will help to fill the gaps between medical needs and novel innovations in the field of medicine.
Highlights
The background of morphology and physiology was established in the Renaissance era between the14th and 16th centuries [1]
This can be achieved through the the fields of detection and diagnosis, such as the use of organic and metal complex-based fluorescent high-throughput screening (HTS), phenotype screening, and virtual screening of precision medicine, as in human immunodeficiency infection using bacteria [7], seizures in zebrafish [8], and sensing nanoprobes tosuch monitor the level of nitric oxide, an important gaseous signaling molecule
Another study indicated that the canine olfaction can detect liquid samples from breast cancer and colorectal cancer memory tests revealed that dogs were superior to rats and that both dogs and rats were superior to humans [29]
Summary
The background of morphology and physiology was established in the Renaissance era between the. To fill the gap between current status and flies, unmet needs medicine, functional discovery and diagnosis are critical in the field of drug discovery This can be achieved through the the fields of detection and diagnosis, such as the use of organic and metal complex-based fluorescent high-throughput screening (HTS), phenotype screening, and virtual screening of precision medicine, as in human immunodeficiency infection using bacteria [7], seizures in zebrafish [8], and sensing nanoprobes tosuch monitor the level of nitric oxide, an important gaseous signaling molecule. To achieve innovation in the diagnosis of rare diseases and early detection of deleterious conditions, several animal models, including worms, have been applied (right) These model systems have contributed to filling unmet needs.
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