Objective To discuss the effect ofrivaroxaban in preventing deep venous thrombosis after large orthopedic operation of lower extremity.Methods Totally 80 patients after lower extremity of large orthopedic operation were selected,they were divided into two groups randomly.The patients in control group (39 cases) were sc injected with enoxaparin through.The patients in observation group (41 cases) were given rivaroxaban orally.The effect of rivaroxaban in preventing deep venous thrombosis after large orthopedic operation of lower extremity were evaluated by hemodynamic indexes,diagnosis index,and complications during 1 months follow-up.Results Before operation,there was no statistical significance on platelet,hemoglobin,and PT values between two groups.Compared with the value before operation,the value ofplatelet and hemoglobin had no significantly change after 3 d of operation.But the PT was increased (P ＜ 0.05).After 3 d of operation,there was no statistical significance on platelet and hemoglobin between two groups.But the PT value of observation was higher than that of control group (P ＜ 0.05).After 1 h operation,there was no statistical significance on D-dimer,Hcy,and hs-CRP between two groups.Compared with the value after 1 h of operation,the values of D-dimer,Hcy,and hs-CRP were decreased significantly (P ＜ 0.05).And the indexes of observation group were lower than those of control group (P ＜ 0.05).After 1 months of operation,although there was no statistical significance on complications between two groups,the incidence rate of secondary bleeding and DVT of control group was higher than that of the observation group.Conclusion The rivaroxaban could prevent DVT well,which is suitable for the anticoagulation therapy after lower extremity of large orthopedic operation with little influence on platelet and hemoglobin.It is worthy of clinical application.

Objective To investigate the effect of rocuronium of on the function of acetylcholine receptor (AchR)/channel in cone neurons of hippocampal cortex in rats.Methods SD rats of both sexes (2-5 days old) were killed by decapitation. Brain was immediately removed and hippocampal cortex was cut into slices which were incubated in decalcified and magnesium-free artificial cerebro-spinal fluid (CSF) and mechanically dissociated and then digested in artificial CFS containing 2.5% trypsin. Cell suspension was prepared. The AchR/channel function was studied in the absence and presence of various concentrations of rocuronium (0, 0.05, 0.1, 0.2, 0.4mmol? L-1) and/or atropine 0.1 mmol ?L-1 using patch clamp technique.Results (1) The conductance, open probability (P0) and short term open constant (?01) were significantly higher in R-0.05 group than those in the control group (R-0) , but there was no significant difference in long term open constant (?02) , short term close constant( (?c1) and long term close constant(?c2) between the two groups. The conductance, P0 ,?01 ,?02 , ?c1, and ?c2 were significantly longer or higher in R-0.0, 0.2 and 0.4 groups than those in control group. (2) There was no significant difference in the conductance, P0 , ?01 , ?02 , ?c1 , and ?c2, between R-0.5 and control group but those in R-0.0, 0.2 and 0.4 groups were significantly higher or longer than control group, when rocuronium was used with atropine. Conclusions AchR/channel ( muscarinic and nicotinic ) in cone neuron of hippocampal cortex were excited by different concentrations of rocuronium. The results suggest that adverse effect may be induced on CNS by rocuronium in case it permeates the injured blood-brain barrier.

Objective To evaluate the effects of dexmedetomidine on the cerebral oxygen metabolism in elderly patients undergoing general anesthesia.Methods Sixty ASA physical status Ⅰ or Ⅱ patients,aged 60-87 yr,scheduled for elective abdominal surgery under general anesthesia,were randomly divided into 2 groups (n =25 each) using a random number table:control group (group C) and dexmedetomidine group (group D).Anesthesia was induced with iv injection of midazolam,fentanyl,atracurium and propofol.The patients were tracheally intubated and mechanically ventilated.In group D,dexmedetomidine 1.0μg/kg was infused intravenously over 20 min before induction of anesthesia,while the equal volume of normal saline was given in group C.Before induction of anesthesia,at 0 and 10 min after tracheal intubation and at the end of operation (T0-3),blood samples were taken from the radial artery and jugular bulb for blood gas analysis.Arteriovenous blood O2 content difference (DajvO2) and cerebral O2 extraction rate (CERO2) were calculated at the same time.The development of emergence agitation and postoperative delirium within 48 h after surgery were recorded.Resets Compared with the baseline values at T0,the Da-jvO2 and CERO2 were significantly decreased at T1-3 in the two groups (P ＜ 0.05).Compared with group C,the Da-jvO2 and CERO2 were significandy decreased at T2-3,and the incidence of emergence agitation and postoperative delirium within 48 h after surgery was decreased in group D (P ＜ 0.05).Conclusion Dexmedetomidine can improve the cerebral oxygen metabolism and reduce the development of postoperative delirium in elderly patients undergoing general anesthesia.

Objective:To anatomically study the external bone graft axis from the pedicle (canal) to the endplate designed for compression healing fractures of the anterior vertebral column in freshly dried vertebral specimens from T10 to L5.Methods:Eight groups of freshly dried vertebral specimens from T10 to L5 (128 vertebral bodies and 256 lateral pedicles and lateral vertebral bodies) were used to observe the vertebral axis of the pedicle (canal), the internal sagittal diameter of the pedicle (canal), and the sagittal diameter of the vertebral body, and the position of vertebral pedicle (canal) axis (f-angle) before design of the external bone graft axis from the pedicle (canal) to the endplate of the compression healing vertebral body. (1) The internal sagittal diameter of the pedicle (canal) was divided into 3 segments. The lateral segment of the vertebral plate was wide, the middle segment of the isthmus of the vertebral arch was narrow and the medial segment of the terminal segment of the vertebral arch was wide. The narrow isthmus of the middle arch (canal) was used as a transposition axis in the design of the axis of the bone graft from the vertebral arch (canal) to the endplate of the compression healing vertebral body. (2) The axis of the vertebral body of the pedicle (canal) was located medial to the transposition axis, parallel to the f-angle at 0° as described by Saillant G. (3) The compression degree of the vertebral body was measured at the outer edge of the lateral anterior column, with Ⅰ° for less than 1/4 compression of the anterior column of the vertebral body, Ⅱ° for 1/4 to 2/4, Ⅲ° for 2/4 to 3/4 and Ⅳ° for more than 3/4 of the compression. (4) The f-angle described by Salliant G at the entry end which was corresponding to the endplate of the compression healing vertebral body was used to design the pedicle (canal) to the outer implant axis of the endplate of the compression healing vertebral body.Results:At an f-angle of 8° to 10°, the bone graft axis was aligned with the Ⅱ° compression healing vertebral endplate on the superior endplate side of the vertebral body axis of the arch; at an f-angle of 16° to 18°, the bone graft axis corresponded to the superior endplate of the Ⅰ° compression healing vertebral body. At an f-angle of -10°~-8°, the bone graft axis corresponded to the Ⅲ° compression healing vertebral endplate on the inferior endplate side of the vertebral body axis of the arch; at an f-angle of -18°~-16°, the bone graft axis corresponded to the inferior endplate of the Ⅳ° compression healing vertebral body.Conclusions:The external axis from the pedicle (canal) to the endplate designed in the present anatomic study for compression healing fractures of the anterior vertebral column allows for safe and easy granular bone implantation due to the toughness of the cortical bone around the arch root (canal) in addition to the precise design of the bone graft axis from the pedicle to the endplate from T10 to L5.