Biochemistry

1901 Submissions

[2] viXra:1901.0281 [pdf] submitted on 2019-01-19 07:01:15

Three–dimensional (3D) Simulations of Human Cancer Cells, Tissues and Tumors for Using in Human Cancer Cells, Tissues and Tumors Diagnosis and Treatment as a Powerful Tool in Human Cancer Cells, Tissues and Tumors Research and Anti–cancer Nano Drugs Sensi

Authors: Alireza Heidari, Ricardo Gobato
Comments: 8 Pages. rends in Res, 2019 doi: 10.15761/TR.1000129 Volume 2(1): 1-2

Three–dimensional (3D) simulations of human cancer cells, tissues and tumors for using in human cancer cells, tissues and tumors diagnosis and treatment as a powerful tool in human cancer cells, tissues and tumors research and anti–cancer Nano drugs sensitivity and delivery area discovery and evaluation such as liquid–based three–dimensional (3D) human cancer cells, tissues and tumors simulations and models for cancer research and anti–cancer Nano drugs sensitivity and delivery area discovery and evaluation while are investigated and considered as a powerful tool in human cancer cells, tissues and tumors research and anti–cancer Nano drugs sensitivity and delivery area discovery and evaluation has strongly recommended by a number of researchers, scientists and scholars around the world.
Category: Biochemistry

[1] viXra:1901.0199 [pdf] submitted on 2019-01-14 06:48:17

Chemical Effects on DNA

Authors: George Rajna
Comments: 38 Pages.

University of Arkansas physics researchers have developed a simple, cost-effective method to study the effects of chemicals on DNA which has potential to improve the development and testing of life-saving treatments. [22] Scientists at the University of Sheffield studying ancient DNA have created a tool allowing them to more accurately identify ancient Eurasian populations, which can be used to test an individual's similarity to ancient people who once roamed the earth. [21] In new research, Hao Yan of Arizona State University and his colleagues describe an innovative DNA walker, capable of rapidly traversing a prepared track. [20] Just like any long polymer chain, DNA tends to form knots. Using technology that allows them to stretch DNA molecules and image the behavior of these knots, MIT researchers have discovered, for the first time, the factors that determine whether a knot moves along the strand or "jams" in place. [19]
Category: Biochemistry