外源性凝血途径和内皮细胞损伤与动脉粥样硬化之间的关系研究

目的探讨外源性凝血途径在动脉粥样硬化(AS)发病中的作用。方法均采用ELISA法测定心肌梗死、脑梗死、脑出血病人及正常对照组血浆TF、FⅦa的含量及不同时期这些物质浓度的变化、同时通过测定内皮细胞损伤的分子标记物vWF、内皮素 -1(ET -1)、总组织因子途径抑制物(TFPI)、组织因子(TF)探讨外源性凝血途径的活化与水平状况及内皮细胞损伤之间的关系。结果心肌梗死、脑梗死、脑出血病人TF、TFPT、ET -1、vWF、FⅦa,血中的浓度较正常对照组高 (P<0.01) ,有非常显著意义。结论外源性凝血途径与内皮细胞损伤和AS有密切相关。     

In Situ Thermal Denaturation of Proteins in Dunning AT-1 Prostate Cancer Cells: Implication for Hyperthermic Cell Injury

The in situ thermal protein denaturation and its correlation with direct hyperthermic cell injury in Dunning AT-1 prostate tumor cells were investigated in this study. The in situ thermal protein denaturation was studied using both Fourier transform infrared spectroscopy (FTIR) and differential scanning calorimetry (DSC). The FTIR spectra at different temperatures show changes in protein secondary structure (from alpha helix to extended beta sheet) during in situ thermal protein denaturation within AT-1 cells. Calorimetric studies using DSC show that endothermic heat release is associated with the in situ thermal protein denaturation. Furthermore, both the secondary structure changes detected by FTIR and the calorimetric changes detected by DSC were quantified and the kinetics of the overall in situ thermal protein denaturation was derived under different heating conditions. The onset temperature where the overall in situ thermal protein denaturation is first detectable was found to be scanning rate dependent (approximately 41 degrees C at 2 degrees C min(-1) and approximately 44 degrees C at 5 degrees C min(-1)). The kinetics of the overall in situ thermal protein denaturation was derived from both DSC and FTIR measurements and was fit using kinetic and statistical models. The kinetic data determined by FTIR and DSC under the same heating conditions match well with each other. The activation energy of the overall in situ thermal protein denaturation is found to be strongly dependent on the temperature range considered (the activation energy ranges from approximately 110 kJ mol(-1) between 44 and 90 degrees C to approximately 750 kJ mol(-1) between 44 and 50 degrees C). However, its dependence on heating rate is negligible. Several denaturation peaks, including a dominant one between approximately 62 and 65 degrees C, are identifiable from both the DSC and the FTIR results. To investigate directly the relationship between thermally induced cell injury and the in situ thermal protein denaturation, both acute (propidium iodide dye exclusion, assessed 3-h postthermal treatment) and chronic (clonogenics, assessed 7-day postthermal treatment) cell injury were quantified using AT-1 cells prepared under the same conditions as for the DSC protein studies. Comparisons of the results from the cell injury studies and the DSC protein denaturation studies show that the overall in situ thermal protein denaturation correlates well with both the acute and the chronic cell injury, which suggests that overall in situ thermal protein denaturation is an important mechanism of direct hyperthermic cell injury in AT-1 cells at the macromolecular level.     

Mechanical Characterization of an In Vitro Device Designed to Quantitatively Injure Living Brain Tissue

Due to the nonlinear, viscoelastic material properties of brain, its mechanical response is dependent upon its total strain history. Therefore, a low strain rate, large strain will likely produce a tissue injury unique from that due to a high strain rate, moderate strain. Due to a lack of current understanding of specific in vivo physiological injury mechanisms, a priori assumptions cannot be made that a low strain rate injury induced by currently employed in vitro injury devices is representative of clinical, nonimpact, inertial head injuries. In the present study, an in vitro system capable of mechanically injuring cultured tissue at high strain rates was designed and characterized. The design of the device was based upon existing systems in which a clamped membrane, on which cells have been cultured, is deformed. However, the present system incorporates three substantial improvements: (1) noncontact measurement of the membrane deflection during injury; (2) precise and independent control over several characteristics of the deflection; and (3) generation of mechanical insults over a wide range of strains (up to 0.65) and strain rates (up to 15s^–1). Such a system will be valuable in the elucidation of the mechanisms of mechanical trauma and determination of injury tolerance criteria on a cellular level utilizing appropriate mechanical injury parameters.     

FK506 (tacrolimus) improves lung injury through inhibition of Fas-mediated inflammation

Objective To investigate whether FK506 (tacrolimus) can inhibit Fas- or A23187-induced interleukin (IL)-8 expression and cell death in A549 human alveolar epithelial cells, plus Fas-mediated acute lung injury in vivo. Methods Assays for IL-8, cell death, and caspase-3 activity were performed. A549 cells were treated with 25 μmol A23187 or 0.2 μg/ml agonistic anti-Fas antibody plus 5 ng/ml interferon-gamma (IFN-γ). Tacrolimus was treated at 0.1–10 ng/ml. For in vivo experiment, agonistic anti-Fas antibody (Jo2) at 2.5 μg/g was intratracheally instilled into C57BL/6 mice. Neutrophils and protein contents in bronchoalveolar lavage (BAL) fluid were measured within 24 h of instillation. Mice were orally treated with 32 mg/kg of tacrolimus 24 h and 1 h prior to instillation. Results Both Fas and A23187 caused significant IL-8 expression and cell death in A549 cells. Tacrolimus inhibited A23187-induced IL-8 expression alone while it protected all Fas-mediated responses. Mice instilled intratracheally with Jo2 at 2.5 μg/g had significant increases in neutrophils, protein contents in BAL fluid and in expression of chemoattractants for neutrophils. These increases were reversed by tacrolimus. Conclusions Tacrolimus serves as a therapeutic option for improving lung injury through inhibition of Fas-mediated inflammation. Received 7 November 2005; returned for revision 28 December 2005; accepted by G. Wallace 2 February 2006     

肢体缺血/再灌注后氧自由基与Bax蛋白、细胞凋亡的关系

目的　阐明氧自由基与Bax蛋白、细胞凋亡在大鼠肢体缺血 /再灌注不同时相中的变化规律及相互关系。方法　采用大鼠股动脉夹闭模型 ,阻断股动脉血流 5h后再灌注 ,设立缺血组、再灌注组 ,再灌注组设立 1,6 ,12 ,2 4h 4个检测时相 ,应用硫代巴比妥酸法测定肌肉组织中脂质过氧化产物丙二醛 (MDA)水平 ,应用免疫组化方法测定Bax蛋白表达的变化 ,应用原位末端标记法及电镜方法观察细胞凋亡现象。结果　随着再灌注时间的延长 ,MDA水平、Bax蛋白表达强度、细胞凋亡指数 (AI)进行性升高 ,且三者呈显著正相关。结论　氧自由基与细胞凋亡同时参与肢体再灌注损伤 ,氧自由基可能通过调节Bax蛋白表达促进细胞凋亡的发生。     

Energy deficiency,calcium overload or oxidative stress: Possible causes of irreversible ischemic myocardial injury

Summary After prolonged ischemia or hypoxia myocardial injury is not reversed but exacerbated by a resupply of the tissue with oxygen and substrates. The mechanism by which reversible ischemic or hypoxic myocardial injury becomes irreversible is not yet understood. It has been debated whether reperfusion injury merely uncovers pre-existing irreversible injury, or is indeed caused by the reperfusion/reoxygenation process. In recent years, three theories have been discussed that relate the onset of irreversibility either to: a critical energy loss; a critical accumulation of cellular calcium; or to the deleterious effects of free radical formation. In certain experimental models for each of these theories favourable results have been obtained. Current research suggests that absolute reversibility thresholds in energy depletion or calcium accumulation in the ischemic or hypoxic cell do not exist. A key role of free radical injury for reperfusion injury must also be questioned. There is, however, evidence that in tissue reversibility of ischemic cardiomyocyte injury is limited by conditions that make calcium-induced hypercontracture upon reoxygenation unavoidable. This occurs when, by hypercontracture, mutual mechanical disruption of the cells destroys the tissue. From isolated cardiomyocytes that are able to metabolically survive hypercontracture it has been observed that these metabolic conditions do not represent the last biological possibility to reverse injury.     

Relationship between core temperature and skin blood flux in lower limbs during prolonged arm exercise in persons with spinal cord injury

The purposes of the present study were to examine the response of the skin blood flux (SBF) in the paralyzed lower limbs of persons with spinal cord injury (PSCI) and to clarify the relationship between the SBF and core temperature during prolonged arm exercise. Eight male PSCI with lesions from T6 to L5 and six male control subjects (CS) participated in this study. The subjects rested for 60 min and then performed arm-cranking exercise at 20 W for 30 min at 25 °C. The tympanic membrane temperature (T _ty) and SBF in the anterior thigh (SBFT) and in the posterior calf (SBFC) were continuously measured throughout the experiment. The SBFC did not change in either PSCI or CS during the experiment. The SBFT in four PSCI with high lesions (T6 to T12), remained unchanged during exercise. The SBFT in the other four PSCI with low lesions (T12 to L5, SBFT+) began to elevate markedly when the T t, exceeded a threshold temperature of 36.69 °C. The pattern of increase of SBFT in SBFT+ was similar to that in CS, although onset of the increase in SBFT was delayed and the peak of SBFT during exercise was significantly lower in comparison with the CS. We consider that these differences between the SBFT+ and CS were largely attributable to the lowerT _ty in the former group, which took a prolonged time to reach the threshold of 36.69 °C.     

Cervical muscle response to trunk flexion in whiplash-type lateral impacts

The purpose of this study was to determine the response of the cervical muscles to increasing low-velocity, whiplash-type lateral impacts when the occupant is seated out of the recommended driving position (neutral posture). Twenty healthy volunteers were subjected to left lateral impacts of 4.1, 7.7, 10.5, and 13.7 m/s² acceleration, with their trunk flexed by 45° and laterally flexed to the right and left also by 45° at the time of impact. Bilateral electromyograms of the sternocleidomastoids, trapezii, and splenii capitis were recorded. Under these conditions of trunk-flexed postures, in a left lateral impact, muscle responses were of generally low magnitude with the trunk flexed to either the left or right. Even at the highest acceleration of 13.7 m/s², all muscles generated less than 37% of their known maximal voluntary contraction electromyogram. Also, in these left lateral impacts, the right splenius capitis showed a greater EMG response than the left splenius capitis regardless of whether the subject was flexed to the right or left at the time of impact. The right splenius capitis (the one contralateral to the left lateral impact direction) was more active than its counterpart. Compared to what is known for EMG responses with an occupant in the neutral posture, the right sternocleidomastoid (usually the most active muscle in a left lateral collision) was significantly less-active with trunk flexion than with neutral posture conditions (P<0.01). In the absence of bodily impact, the flexed trunk posture does not produce a biomechanical response that would increase the likelihood of cervical muscle injury in low velocity lateral impacts, and may lessen the risk of injury for some muscles.     

Effects of Crowding on the Thermal Stability of Heterogeneous Protein Solutions

Crowding can substantially affect the transition of a protein between its native (N) and unfolded (U) states via volume exclusion effects. Also, it influences considerably the aggregation (A) of unfolded proteins. To examine the details, we developed an approach for computing the kinetic rates of the process N ↔ U → A in which the concentration of the protein is explicitly taken into account. We then compute the relative change with temperature of the protein denaturation for various fractional volume occupancies and partition of proteins in solution. The analysis indicates that, in protein solutions in which the average distance between proteins is comparable with the radius of gyration of an unfolded protein, steric effects increase the stability of the proteins which are in compact, native states. In heterogeneous protein solutions containing various types of proteins with different thermal stabilities, the unfolding of the most thermolabile proteins will increase the stability of the other proteins. The results shed light on the way proteins change the thermal stability of a cell as they unfold and aggregate. This study may be valuable in questions related to the dynamics of thermal injuries.     

肩胛骨前后联合入路治疗陈旧性浮肩损伤（附6例报告）

目的：探讨肩胛骨前后联合入路治疗陈旧性浮肩损伤的临床疗效。方法：采用肩胛骨前后联合入路对6例陈旧性浮肩损伤进行手术治疗。结果：根据Herscovici功能评估标准，其中优1例，良2例，可3例，无血管神经副损伤。结论：采用肩胛骨前后联合入路处理陈旧性浮肩损伤，术野显露清楚，易于操作与复位固定，可以有效地避开血管神经，安全可靠。