突

4DRG was co-culture with sciatic nerve segment in 10鸖 DMEM;the axons were longer and surround the sciatic nerve segment which was regard as anew evidence for chemotropism.

结果：(1)在无血清条件下单独培养的DRG，背根神经节的轴突数目众多，外形纤细弯曲，不成束，并且施万细胞和成纤维细胞稀少，所以可以排除两者对轴突生长的影响，为观察来源于变性坐骨神经段的可溶性因子对轴突生长的作用提供了有利条件；(2)在无血清条件下DRG和变性坐骨神经段联合培养，①先单独培养DRG，4天后待神经元轴突长出，再与坐骨神经段联合培养，观察到神经元的轴突数目减少，外形挺直，部分轴突之间相互粘附成束；②变性坐骨神经段和DRG同时联合培养，神经元的轴突数目明显减少，外形粗壮，轴突之间相互粘附成束；(3)有血清条件下单独培养DRG，轴突数目较多，外形挺直，长短不一，部分神经元的轴突之间相互粘附，施万细胞和成纤维细胞数目众多，观察到的轴突生长情况受到施万细胞和成纤维细胞的直接或者间接的影响。

Results in those 30 samples, the styloid process showed with high quality inⅠgroup is 25,in Ⅱ group is 27,about length measurement, as a whole, the difference of the two groups is little.

结果 30例中茎突能清晰完整显示的常规茎突侧位有25例，而用口腔全景机拍摄的茎突有27例，在茎突长度测量方面，从两种摄影方法拍摄的茎突影像上测得的茎突长度无显著的统计学差异。

Cellular structure is simple and has intermediate neurons, which can survive a longer period in vitro. Amphibial sympathetic ganglions show various postsynaptic potential including fast excitatory postsynaptic potential. Slow inhibitory postsynaptic potential.Slow exeitatory postsyn...

两栖动物交感神经节表现出多种突触后电位，包括快兴奋性突触后电位，慢抑制性突触后电位，慢兴奋性突触后电位，晚期慢兴奋性突触后电位，同时还表现多种突触塑性，说明该神经节具有信息存储功能，因此，两栖动物交感神经节可作为研究学习与记忆的模型系统。

Gliosis is resulted in TLE. The synapse consists of the presynaptic and postsynaptic terminals, which in many synapses are surrounded by glial cell.

颞叶癫痫可导致神经系统胶质增生，突触后终端与胶质细胞之间形成突触，突触后终端的树突棘的形态学的变化引起突触结构的改变，与胶质细胞之间形成的突触为异位突触，引起海马内环路性质的变化，从而提高致痫性。

Infratemporal space and parapharyngeal space were divided by the line from styloid process to medial or lateral pterygoid plate. Lateral pterygoid, styloid process, medial pterygoid plate and lateral pterygoid plate were important anatomical marks for imaging diagnosis.

自茎突至翼突内侧板后缘或翼突外侧板前缘的连线可区分颞下间隙与咽旁间隙，翼外肌、茎突、翼突内侧板和翼突外侧板是CT等影像诊断的重要解剖学标志。

Computer Aided Diagnosis Axiography is precise and reliable during the record of condyle movement. On the basis of traditional face bow system, CADIAX use two styli in order to computer the hinge axis; the styli is near to the condyle which diminish the enlargement error and make the record more reliable. Computer technique is adopted by CADIAX, which give a more comprehensive analysis of condyle movement, which can observe the condyle movement in four dimensions. The position of mandible during recording is started from Reference Position, the mandible is posited at a retral position, a more physiological position, and the result is close to reality.

髁突运动轴图描记仪(Computer Aided Diagnosis Axiography)可以准确、可靠的记录分析髁突运动，在传统的面弓记录仪基础上，采用双髁突指针，可以准确计算绞链轴点；测量点与被测髁突距离接近，测量结果更加真实可靠；与计算机技术相结合，数据分析功能更加强大，对髁突运动可以进行四维分析，同步观察双侧髁突的时相特征；记录位置选用参考位置，下颌处于生理后位，记录结果更接近真实情况。

During open/close movement, the distance of condylar movement is smaller than normal occlusion(P.05). During protrusion/retrusion movement, protrusion extent increase,the distance of condylar movement is bigger than normal occlusion(P.05). During lateral excursion, the trace in sagittal plane of the non-working side condyle is more incline than protrusion movement trace and the distance of the left non-working side condylar movement is larger than the right. During mediotrusion/right movement, the left biggest space distance is larger than normal occlusion and the transversal condylar inclination is smallar than normal occlusion when the distance of condylar movement is 5mm, the difference is statistically significant.

在开闭口运动时，双侧髁突运动幅度减小、位移量小于正常牙合者(P.05)；前伸后退运动时，前伸幅度增加，位移量大于正常牙合者(P.05)；侧方运动时，非工作侧髁突在矢状面上的轨迹较前伸轨迹向前下方倾斜度增加，非工作侧髁突空间位移左侧大于右侧，向右侧方运动中，左侧髁突空间位移大于正常牙合者，髁突位移5mm时水平面髁突倾斜度小于正常牙合者，差异有统计学意义。

The optimal entrance point mostly locate at the root of accessoryprocess which adjacent to the mamillary process from L1 to L4, Theadjustable range of entrance points of the 4 segments almost cover theaccessory process, But at L5, The optimal entrance point is much moreoutside away from the accessory process, just at the middle of thetransverse process and the adjustable range of entrance points islimited.

这与钉尾间距的明显变化相一致，手术时应注意调整螺钉钉尖内偏角度观察椎弓根螺钉进钉点发现内外侧螺钉进钉点与内上、外上螺钉进钉点构成接近矩形的梯形区域，最佳进钉点居于内外进钉点中部。L1到L4最佳进钉点位于副突根部靠近乳突处，随着椎体节段下降，进钉点逐渐移向外侧，L1最佳进钉点基本在副突根部骨嵴内侧缘，L2、L3最佳进钉点基本在副突根部骨嵴上，L4最佳进钉点基本在副突根部骨嵴外侧缘。L1到L4可选进钉点范围几乎均包含副突骨嵴。L5最佳进钉点则明显偏外，多数位于副突根部与横突外端连线的中内1／3。

From the simulations, we can see the distributions and transmission of strain and stress in model under different loadings, and the results explained the fractures very well. 4. Similarly, a axis FEM model was constructed to simulate the axis fracture, emphasized on the odontoid process. Three kind of odontoid process fracture were analysed on this model, which occurred respectively on the tip, the middle and the fundus. The results gave the best angle to fracture the odontoid process of the axis.

四、建立了枢椎的三维有限元模型，对枢椎齿状突骨折机理进行了理论上的研究，重点针对临床上齿突骨折的三种分类：1、齿突尖骨折；2、齿突腰部骨折；3、齿突基底部骨折，赋予齿状突在矢状面沿各种角度下受力条件，模拟衰椎前弓、襄椎横韧带以及CZ－3棘间韧带对枢椎造成的暴力破坏，确定了最可能引起齿状突暴力骨折的受力角度。

Similarly, a axis FEM model was constructed to simulate the axis fracture, emphasized on the odontoid process. Three kind of odontoid process fracture were analysed on this model, which occurred respectively on the tip, the middle and the fundus. The results gave the best angle to fracture the odontoid process of the axis.

四、建立了枢椎的三维有限元模型，对枢椎齿状突骨折机理进行了理论上的研究，重点针对临床上齿突骨折的三种分类：1、齿突尖骨折：2、齿突腰部骨折：3、齿突基底部骨折，赋予齿状突在矢状面沿各种角度下受力条件，模拟寰椎前弓、寰椎横韧带以及C2-3棘间韧带对枢椎造成的暴力破坏，确定了最可能引起齿状突暴力骨折的受力角度。

anticlimactic：突降法的, 突减的(兴趣等), 虎头蛇尾的

anticlerical | 反圣职者的, 反对教权的 | anticlimactic | 突降法的, 突减的(兴趣等), 虎头蛇尾的 | anticlimax | 突降法, 突减, 虎头蛇尾

synaptic cleft：突触间隙

以生物电流作为信息媒介,某此低等动物比较发达,哺乳动物及人很少.在电镜下观察,突触由三部分构成,分别是突触前成分(presynaptic element),突触间隙(synaptic cleft)和突触后成分(postsynaptic element).突触前,

presynaptic inhibition：突触前抑制

2.突触前抑制 突触前抑制(presynaptic inhibition)在中枢内广泛存在,尤其多见于感觉传人通路中,对调节感觉传人活动具有重要意义. 如图10-12所示,轴突末梢A与运动神经元构成轴突一胞体式突触;轴突末梢B与末梢A构成轴突一轴突式突触,

inhibitory synapse：抑制性突触

可分为 (excitatory synapse)和抑制性突触 (inhibitory synapse). 突触的信息传递使突触后膜去极化,产生兴奋性的突触后电位的称为兴奋性突触. 突触的信息传递使突触后膜超极化,产生抑制性的突触后电位的称为抑制性突触.

styloid process：茎突

(五)茎突 茎突(styloid process)起于颞骨鼓部的下面,伸向前下方,呈细长形,长短不一,平均长约25mm;远端有茎突咽肌、茎突舌肌、茎突舌骨肌、茎突舌骨韧带和茎突下颌韧带附着.

electrical synapse：电突触

(一)几类重要的突触传递 根据突触传递媒介物性质的不同,可将突触分为化学性突触(chemical synapse)和电突触(electrical synapse)两大类,前者的信息传递媒介物是神经 递质,而后者的信息传递媒介物则为局部电流.化学性突触一般由突触前成分,

synaptic vesicle：突触囊泡

当神经冲动到来时,贮存于突触囊泡(synaptic vesicle)内的神经递质便进行排放,通过突触间隙扩散到突触后膜,引起突触后成分去极化或超极化. 因此,有兴奋性突触和抑制性突触之称. 神经冲动通过化学突触时有明显的突触延搁(synaptic delay)(约0.5-2 ms).

reciprocal synapses：交互性突触

还存在树突-树突式、树突-胞体式、树突-轴突式、胞体-树突式、胞体-胞体式、胞体-轴突式突触,以及两个化学性突触或化学性突触与电突触组合而成的串联性突触(serial synapses)、交互性突触(reciprocal synapses)和混合性突触(mi

serial synapses：串联性突触

此外,由于中枢存在由大量局部神经元构成的局部神经元回路(见后文),还存在树突-树突式、树突-胞体式、树突-轴突式、胞体-树突式、胞体-胞体式、胞体-轴突式突触,以及两个化学性突触或化学性突触与电突触组合而成的串联性突触(serial synapses)、交互性突触(re

mixed synapses：混合性突触

还存在树突-树突式、树突-胞体式、树突-轴突式、胞体-树突式、胞体-胞体式、胞体-轴突式突触,以及两个化学性突触或化学性突触与电突触组合而成的串联性突触(serial synapses)、交互性突触(reciprocal synapses)和混合性突触(mixed synapses)等(图10-3B)