[Current status and prospect of translational medicine in nanotechnology].

Nowadays, nanotechnologies have shown wide application foreground in the biomedical field of medicine laboratory tests, drug delivery, gene therapy and bioremediation. However, in recent years, nanomaterials have been labeled poisonous, because of the disputes and misunderstandings of mainstream views on their safety. Besides, for the barriers of technical issues in preparation like: (1) low efficacy (poor PK & PD and low drug loading), (2) high cost (irreproducibility and difficulty in scale up), little of that research has been successfully translated into commercial products. Currently, along with the new theory of "physical damage is the origin of nanotoxicity", biodegradability and biocompatibility of nanomaterials are listed as the basic principle of safe application of nanomaterials. Combining scientific design based on molecular level with precision control of process engineering will provide a new strategy to overcome the core technical challenges. New turning point of translational medicine in nanotechnology may emerge.

Three-dimensional reconstruction of the uterine vascular supply through vascular casting and thin slice computed tomography scanning.

It was the objective of this study to construct a model of the uterine vascular supply through vascular casting and thin slice computed tomography scanning. This will provide a teaching aide for the understanding of uterine artery embolization (UAE) procedures, as well as normal uterine and ovarian arterial anatomy. Using 20% chlorinated poly vinyl chloride, we infused and cast a set of a normal uterus, vagina and bilateral adnexa through the uterine artery and ovarian artery. After thin slice CT scanning, we obtained the three-dimensional (3D) reconstruction by maximum intensity projection (MIP) and surface-shaded display (SSD), and then observed its figure and characteristics. A model of the uterine vascular supply can be successfully reconstructed by vascular casting and thin slice CT scanning. The 3D reconstruction offers a clear view of the course of the uterine artery and its blood supply distribution. It has two major branches: The intramuscular uterine branch and the cervicovaginal branch (1). Blood supply is generally unilateral, with communicating branches between the two sides and possible anastomoses between the arterial blood supply of the uterus and the ovaries. The major blood supply of the cervix comes from the cervicovaginal branch of the uterine artery, while the vaginal arterial supply derives directly from the internal iliac artery. The CT technique allows real-time 360 degrees rotation and changes in model for in-depth study of the vascular network and its adjacent tissues. It is possible to construct an in vitro uterine arterial network by vascular casting and CT scanning, which can provide unique insight into the female genitourinary system arterial network. Based on this, we can create reconstructions as well as models for different diseases such as leiomyomata, adenomyosis, and endometrial cancer. These models will provide morphological evidence to the interventional therapy and UAE teaching in Obstetrics and Gynecology.

[Toxicological study of fresh water microcystins].

Microcystins are a group of toxins that are produced by fresh water cyanobacteria. They are bioactive materials which are hepatotoxic. They can inhibit serine/threonine protein phosphatase (PP1 and PP2A), breaking the balance between protein phosporylation and phosphorylysis. They present a wide range of harmful effects to human body, such as hepatotoxicity and tumor promotion. They also affect other organs like kidney and intestines. Recently, more and more attention is being paid to microcystins worldwide. This review summarizes the progress in the toxicological study of fresh water microcystins.