To clone and sequence the human tissue kallikrein gene of Chinese, and to construct eukaryotic expression recombinant of KK, total RNA was extracted from human pancreas and human tissue kallikrein gene cDNA was amplified by PCR after reverse-transcription by using Oligo(dT) primer. The original kallikrein cDNA was recovered and filled with Klenow enzyme and inserted into KS plasmid. After restriction endonuclease digestion, KK cDNA was sequenced by ABI377 analyzer. Then the KK gene was amplified from pBluescript KSKK and inserted into pcDNA3. A sequence comparison showed that the cloned kallikrein gene was only one nucleotide different from that reported in the Genbank. The coding amino acid was Asp in the Genbank gene, while the coding amino acid of Chinese kallikrein gene was Asn. The KK cDNA fragment was inserted into the eukaryotic expression vector pcDNA3. The cloned kallikrein gene and the pcDNA3KK can be used for further study in gene therapy.. .

To investigate the effects of carbamazepine (CBZ) on the plasma concentrations of valproic acid (VPA) and its toxic metabolite 2-propyl-4-pentenoic acid (4-ene VPA) in epileptic patients, the plasma concentrations of VPA and 4-ene VPA were determined, and the effect of CBZ on pharmacokinetics of VPA was evaluated. All patients had been divided into two groups (VPA group, n = 87; and VPA+CBZ group, n = 19). As compared to VPA group, the combination of CBZ significantly (P < 0.01) decreased the trough concentration of VPA [VPA group, (69.5 +/- 28.8) microg x mL(-1); VPA+CBZ group, (46.3 +/- 25.6) microg x mL(-1)] and does-adjusted VPA trough concentration [VPA group, (4.89 +/- 2.21) microg x mL(-1) x mg(-1) x kg(-1); VPA+CBZ group, (3.14 +/- 1.74) microg x mL(-1) x mg(-1) x kg(-1)]. However, the addition of CBZ did not influence the concentration of 4-ene VPA. The present study revealed that coadministration of CBZ can reduce VPA plasma concentration and may impact VPA clinical effect, therefore therapeutic drug mornitoring of VPA should be used when combined use of CBZ and VPA.

To clone and sequence the human tissue kallikrein gene of Chinese, and to construct eukaryotic expression recombinant of KK, total RNA was extracted from human pancreas and human tissue kallikrein gene cDNA was amplified by PCR after reverse-transcription by using Oligo(dT)primer. The original kallikrein cDNA was recovered and filled with Klenow enzyme and inserted into KS plasmid. After restriction endonuclease digestion, KK cDNA was sequenced by ABI 377 analyzer.Then the KKgene was amplified from pBluescript KSKK and inserted into pcDNA3. A sequence comparison showed that the cloned kallikrein gene was only one nucleotide different from that reported in the Genbank. The coding amino acid was Asp in the Genbank gene, while the coding amino acid of Chinese kallikrein gene was Asn. The KK cDNA fragment was inserted into the eukaryotic expression vector pcDNA3. The cloned kallikrein gene and the pcDNA3KK can be used for further study in gene therapy...

Lumbar degenerative disease is one of the most common diseases in orthopaedic clinics, and the chronic low back pain caused by it seriously affects patients' living quality. Currently, intervertebral fusion and rigid fixation are the main surgical methods for lumbar degenerative disease. Although the intervertebral fusion and rigid fixation can achieve a higher fusion rate, due to the stress concentration of adjacent segments, the adjacent segment degeneration may occur and make the patient's satisfaction rate much lower than the imaging fusion rate. Dynamic fixation is a new fixing concept, which can control the abnormal motion of the spine segment while retaining part of the movement of the fixed segment. Moreover, dynamic fixation is also beneficial to reduce the degeneration of adjacent segments and the incidence of breakage of internal fixation. Nowadays, various lumbar transpedicular dynamic fixation systems have appeared on the market. Most of these transpedicular dynamic fixation systems are derived from the design of pedicle screws and rods used in spinal fusion surgery in the 1980 s and 1990 s. The original intention of their design is to stabilize the abnormal segments and reduce the pressure on degenerated intervertebral discs and facet joints, while maintaining the normal movement of relevant segments. By reviewing the biomechanical research, clinical efficacy, existing problems and advantages and disadvantages of common backward lumbar transpedicular dynamic fixation systems, this article intends to provide new ideas for the improvement of the backward lumbar transpedicular dynamic fixation system design, as well as offering surgical treatment strategies for clinicians.