Objective To explore the image characteristics of the opening of the blood brain barrier (BBB) at the early stages of severely scalded rabbits. Methods Twenty-six rabbits inflicted with 50% total burn surface area (TBSA) of Ⅲ degree were randomized into 7 groups: pre-scald, post-scald at 1, 2, 3, 4, 5, and 6 h groups. The spiral CT (SCT) and MRI were used to observe the image changes during the corresponding phases. Samples from the anterior cortex, temporal lobe, posterior cortex, cerebellum, and brain stem were examined by light and transmission electron microscopy (TEM), respectively. Results The pathological features showed that neurons and oligodendrocytes swelled lightly and blood vessels were congested and dilated at 3-4 h after scald. CT image changes were found at 5 h after scald and became more remarkable at 6 h after scald. MRI image changes could not be found within 6 h after scald. Conclusion The opening of BBB is earlier than the formation of edema. Enhanced CT plays an important role in manifesting the opening of BBB at the early stages of severely scalded rabbits.

Objective To explore the cause, influencing factor and possible solving method of transient adverse reactions during the operation. Methods Sixteen healthy beagles were undergone virtual PLDD. The changes of vertebral discs and the surrounding tissues were observed by high resolution CT and MRI at different periods after the operation, and the same investigation procedure was carried out after the sacrifice of beagles. Results The beagles of the conventional vaporization group occasionally had limb tic and whining in the operations. Pieces of necrosis and edema could be found in the tissues of intervertebral foramen at the paracentetic side. The histological changes in the negative pressure suction group were less than those in the conventional group. Conclusion The reversible damages of the surrounding tissuses were observed in the conventional group and continuing negative pressure suction during the operations can prevent the damages to the surrounding tissues, all of the changes could be clearly displayed by CT and MRI scan.

Plaque pH detection technology can detect the risk of caries and assist in the prevention of caries, with a mature theory and a relatively simple operation. With the increasing demand for clinical caries risk detection technology and the rapid development of microelectrode techniques, there is an increasing variety of types of microelectrodes that can detect the pH of dental plaque, including glass microelectrodes, metal oxide microelectrodes and ion-sensitive field effect transistors. The glass microelectrode was the first microelectrode to be applied in this field, but its structure is weak. Among the various options, the iridium oxide microelectrode has become the most promising caries risk detection electrode in recent years because of its high strength and excellent response. Metal oxide microelectrodes can also effectively compensate for the insufficient strength of glass microelectrodes. With advances in electrode technology, miniaturized, sensitive ion-sensitive field effect transistors have attracted the attention of researchers. Scientists have also recently developed a way to detect the pH of dental plaque with an optical no-contact technique. Optical contactless detection technology will not damage the dental plaque structure, so it has great research and clinical prospects. Future research will further improve the strength and performance of these electrodes on the premise of ensuring miniaturization and achieving noncontact detection.