ABSTRACT
BACKGROUND: At present, the basic molecular etiological mechanism and core regulatory network of deep vein thrombosis (DVT) remains uncertain, and there is not an ideal measure for early diagnosis of DVT. OBJECTIVE: To study the underlying impact of cathepsin L/G in DVT rat model. METHODS: DVT rat models (n = 50) were established by clamping both femoral vein in three different positions within 3 seconds with mosquito forceps and fixing with cast. According to different observation phases and biological situations of the femoral vein thrombosis, model rats were divided into thrombogenesis group, pre-thrombogenesis group and non-thrombogenesis group. An additional 10 normal rats served as control group. Femoral vein was obtained at corresponding time points to exact total RNA. After a gene chip-based screening, the data of gene expression were further dissected by real-time PCR. RESULTS AND CONCLUSUON: Gene chip hybridization analysis results demonstrated that differential expression of cathepsin L/G gene was significant among groups, and the expression was greatest in the thrombogenesis group, followed by pre-thrombogenesis and non-thrombogenesis groups, which was significantly greater than the control group (P < 0.05). Real-time PCR analysis results were consistent with gene chip hybridization analysis results. These indicate that DVT is associated with an increase in expression of cathepsin L/G in local venous vascular wall, and they may be candidate molecular markers for early diagnosis of deep vein thrombosis.
ABSTRACT
BACKGROUND: Deep venous thrombosis (DVT) always occurs after orthopedic surgery. At present, clinical diagnosis of DVT has been lack of an effective measuring means for a long time. Cathepsin may be an effective biological marker of DVT. OBJECTIVE: To study the expression change of cathepsin B and cathepsin C in the rat blood cells before and after DVT and to investigate the feasibility of cathepsin B and cathepsin C as candidate molecular markers for early diagnosis of DVT. METHODS: Totally 100 Sprague Dawley rats were randomly divided into normal control group (n=10) and model group (n=90). Rat traumatic deep vein thrombosis models were established by clamping the femoral vein and fixing the bilateral hind limbs. According to observation time points and the different situations of thrombosis, rat models were assigned to three subgroups: pre-thrombosis, intra-thrombosis, and non-thrombosis. Blood RNA of each group was extracted and reverse transcribed into cDNA. The expression of cathepsin B and cathepsin C in blood cells was detected using real-time fluorescence quantitative PCR. RESULTS AND CONCLUSUON: Expression of cathepsin B and cathepsin C in the blood cells was obviously expressed in the intra-thrombosis subgroup. There was no significant difference in cathepsin B and cathepsin C expression between pre-thrombosis, non-thrombosis groups and normal control group. These findings suggest that cathepsin B and cathepsin C are closely related to DVP and they can be used as the candidate molecular markers for early diagnosis of DVT.
ABSTRACT
BACKGROUND:There is lack of an effective measuring means to diagnose deep venous thrombosis (DVT) in clinic.KLF2 and KLF4 are down-expressed at prethrombotic state,which may be served as predictive molecular markers to diagnose DVT.OBJECTIVE:To explore the feasibility of KLF2 and KLF4 as molecular markers to prediagnose DVT in rats.METHODS:Totally 90 rats were obtained from 100 rats to establish traumatic DVT models and divided into the prethrombotic,thrombosis crest-time and non-thrombosis groups.The remained 10 rats served as control group.Rat blood was collected at each time point,and the expressions of KLF2 and KLF4 were detected by real-time PCR.RESULTS AND CONCLUSION:The KLF2 and KLF4 mRNA expressions in the prethrombotic group and thrombosis crest-time group were lower than that of the control group.However,the KLF2 and KLF4 mRNA expressions in the non-thrombosis group was higher than that of the control group.Therefore,KLF2 and KLF4 may be candidate molecular markers for prediagnosis of DVT in rats.
ABSTRACT
BACKGROUND:Studies in recent years have demonstrated that arginase Ⅰ contribute to the process of numerous cardiovascular diseases,however,most of studies focus on arteries,few regarding venous diseases.OBJECTIVE:To explore the changes of arginase Ⅰ expression in rat traumatic deep venous thrombosis models,and to analyze the possible function of arginase Ⅰ in deep venous thrombosis formation.METHODS:Totally 100 Sprague Dawley rats were randomly divided into the control and model groups.Traumatic deep venous thrombosis models were established by clamping the femoral vein and immobilizing the bilateral hind limbs (hip spica cast fixation),and assigned into initial thrombosis,peak thrombosis and non-thrombosis groups according to different observing time points and pathophysiological situations of thrombosis.Whole blood RNA of each group was extracted,and the change of arginase I expression in blood cells of each group was detected by real-time PCR.RESULTS AND CONCLUSUON:Expression of arginase Ⅰ in the peak thrombosis group was significantly increased compared with other 3 groups (P < 0.01).There were no significances among control,initial thrombosis and non-thrombosis groups (P > 0.05).The finding demonstrated that arginase Ⅰ is closely related to deep vein thrombosis formation.
ABSTRACT
BACKGROUND:The molecular mechanism of traumatic deep vein thrombosis is complex.Numerous studies focus on clinical observation and epidemiology,but its molecular mechanism has not been a new breakthrough.OBJECTIVE:By use of gene array technology,this study was aimed to study the expression changes of matrix metalloproteinases in rat models of traumatic deep vein thrombosis,and to explore the roles of matrix metalloproteinases in traumatic deep venous thrombosis.METHODS:A total of 150 SD rats,SPF grade,of 8-12 weeks old,body weight of 250-300 g,were divided at random into normal control group (n=10) and model group (n=140).Rat traumatic deep venous thrombosis models were set up by clamping the femoral vein and fixing the bilateral hind limbs,and the fixation of hip spica with plaster bandage was conducted in each group.Then rats were divided into 7 subgroups:post-traumatic 0.5 hours,post-traumatic 2.5 hours (initial period of thrombosis),post-traumatic 25 hours (thrombogenesis at thrombotic crest-time),post-traumatic 25 hours non-thrombogenesis at the thrombotic crest-time),post-traumatic 72 hours (thrombus resolution),post-traumatic 72 hours thrombus insolution) and post-traumatic 168 hours (nonthrombosis).At the corresponding phasess,the femoral vein tissues were incised,and total RNA of femoral vein was extracted using Trizol one-step method.Applying Genechip Rat Genome 430 2.0 genechips,the gene expressions in femoral vein were detected in different groups.The rate of traumatic deep venous thrombogenesis and non-thrombogenesis,the rate of thrombi solution and insolution were observed;the expressions of matrix metalloproteinases and tissue inhibitor of metalloproteinases at different time phases was detected by gene array data analysis.RESULTS AND CONCLUSION:Three model rats died and the remaining 147 rats were involved in the final analysis.At the post-traumatic 25 hours,the rate of thrombogenesis was 50.5% and nonthrombogenesis was 49.5%.To the post-traumatic 168 hours,the rate of thrombus solution was 56.7% and thrombus insolution was 43.3%.Both matrix metalloproteinases and tissue inhibitor of metalloproteinases exhibited differential expressions in the course of traumatic deep venous thrombosis.Under the thrombus insolution state,matrix metalloproteinases continued to show a high expression,tissue inhibitor of metalloproteinase expression was down-regulated in the thrombus formation,was significantly inhibited in the thrombus insoluUon process.In the process of traumatic deep vein thrombosis and insolution,matrix metalloproteinase was closely related to traumatic deep vein thrombosis,the matrix metalloproteinase/tissue inhibitor of metalloproteinases are likely to affect the biological state of thrombosis.