Objective To review the advancement of heat shock protein 70 (HSP70) vaccine in alimentary canal cancer. Methods Related articles were reviewed. Results HSP70 can integrate with tumor special antigen to form HSP70 polypeptide compound. To activate the special and nonspecial immune response of body, HSP70 can participate in the process of tumor immunity as a “molecular partner”. Conclusion HSP70 has shown alluring perspective in the precaution and treatment of alimentary canal cancer.
Objective To observe the expression of heat shock protein 70 (HSP70) in human liver after hepatic transplantation, and to study its correlation with the occurrence and progression of acute allograft rejection.Methods Fifteen biopsy specimen of allograft liver after transplantation were collected and divided into three groups according to their pathological changes: control group (no rejection), mild acute rejection group, and moderate/serious acute rejection group. The expressions of HSP70 in grafts were detected by using immunohistochemical method and imaging analysis. Results HSP70 was expressed in all 3 groups, and appeared mainly in hepatocellular cytoplasm. The immunohistochemical imaging analysis of HSP70 showed: integral optical density (IOD) which was 30.99±11.14 in the control group was lower than that in the mild acute rejection group (68.84±21.37) and that in the moderate/serious acute rejection group (71.82±19.99), P<0.01; and the IOD in the moderate/serious acute rejection group was higher than that in the mild acute rejection group (P<0.05). Conclusion HSP70 plays a role in cellular protection for allograft liver, and the continuously increasing expression of HSP70 in graft maybe closely relates to the occurrence and progression of acute allograft rejection.
Objective To study the relationship between the expression ratio of heat shock protein (HSP) 70 to C-fos in organs outside the brain after brain concussion and the time of injury in rats, in order to provide a new visual angle for determining injury time of brain concussion. Methods The model of brain concussion was established through free falling method. Then the rats were executed at 30 minutes, 1 hour, and 3, 6, 12, 24, 48, 96, 168, 240, 336 hours after injury. Immunohistochemistry staining of C-fos and HSP70 were used in the materials from the main organs including heart, liver, spleen, lung and kidney. All related experiment results were studied by using a microscope with image analytical system and homologous statistics. Results From 30 minutes to 6 hours after injury, the proportion of HSP70 immuno-positive cells increased slowly, while the proportion of C-fos immuno-positive cells increased rapidly, and the ratio of HSP70/C-fos positive cells was on the decline. From 6 to 12 hours after injury, the proportion of HSP70 immuno-positive cells rose continuously, while the proportion of C-fos immuno-positive cells started to decrease, and the HSP70/C-fos ratio showed a rising tendency. From 12 to 336 hours after injury, the proportion of HSP70 immuno-positive cells decreased slowly, while the proportion of C-fos immuno-positive cells decreased rapidly, and the HSP70/C-fos ratio was still on the rise. Conclusions The proportion of positive cells and ratio of the two markers in the main organs including heart, liver, spleen, lung and kidney are similar to those in the brain of rats after brain concussion. Observing the proportion of positive cells of the two markers together with their ratio in the main organs outside the brain may provide a reference for the determination of injury time after brain concussion.
Objectives To detect expressions of heat shock protein 70 (HSP70) and glial fibrillary acidic protein (GFAP) , and to estimate the post-injury interval after concussion of brain via the ratios of percentage of HSP70/GFAP-positive cells. Methods We established a brain concussion model of rat. Tissue levels of HSP70 and GFAP were determined by immunohistochemical staining at different time points after injury. Finally, the relationship between the ratio of percentage of HSP70/GFAP-positive cells and the post-injury interval was measured. Results The ratio of percentage of positive cells (increased from 7.15 to 11.73) and the percentage of HSP70-positive cells (P<0.05, compared with control group) increased, and the percentage of GFAP-positive cells did not change remarkably (P<0.05, compared with control group); the post-injury interval was between 0.5 hour and 3 hours. High ratio (>6.66) and high percentage of HSP70 and GFAP-positive cells (P<0.05, compared with control group) indicated the post-injury interval was between 3 and 12 hours. A low ratio (<6.66) and high percentage of HSP70 and GFAP-positive cells (P<0.05, compared with control group) suggested that the post-injury interval was later than 12 hours. Conclusion By analyzing the variation rule of the ratio of percentage positive cells after brain concussion, the post-injury interval after concussion of brain could be estimated.