The Food-Crushing Reflex and Its Inhibition

Lauri H. Vaahtoniemi
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Abstract

Anterior tooth (ANT) contacts induce a short-latency reflex inhibition of the human jaw-closing muscles. The jaw is a rigid class 1 lever for pinpoint targeting muscle force into a single bite point, the pivoting food particle. Seesaw reflex movements around the food particle fulcrum multiply the food-crushing force. Unpredictable jolts of reaction force caused by food crushing are subjected to the rostral ANT and caudally to the two articulate ends of the jaw triangle. The compression/distraction strains of food crushing must be monitored and inhibited by withdrawal reflexes. The mesencephalic ganglion (Vmes), neural myelin sheath, and muscle stretch receptors evolved subsequently to the advent of jaws to improve the velocity of proprioceptive and withdrawal reflexes. In mammalians, the spindles of the taut motor units, stretched by the food fulcrum, send excitatory monosynaptic feedback for the efferent neurons of the respective ipsilateral muscle units via the Vmes. In the Vmes, the spindle-input-mediating afferent neurons are coupled with another source of afferent feedback, which is also excitatory, from the back tooth (BAT) mechanoreceptors. The two sources of excitatory pulses are summated and targeted for the efferent neurons to boost the stretched and taut motor units. Likewise, the afferent feedback from the ANT mechanoreceptors is also coupled in the Vmes with concomitant feedback from spindles. The ANT output, however, is inhibitory to negate the excitatory feedback from the stretched jaw muscle units. The inhibitory feed from the anterior teeth temporarily blocks the excitatory potential of the masticatory motor efferent neurons to protect the anterior teeth and jaw joints from inadvertent strains. The inhibitory inputs from the anterior teeth alternate with the excitatory inputs from the BAT to determine which jaw-closing muscle units are activated or inhibited at any given instant of food crushing. The Vmes exists in all jawed vertebrates, and its evolution was probably motivated by demands for the control of bite force. The monosynaptic unilateral food-crushing excitatory and inhibitory reflexes (UFCRs) override the coexisting bilaterally executed feed for the jaw muscles from the central nervous system. The hypothesis proposed in this study is that the Vmes-mediated UFCRs combine neural inputs from tooth contacts with concomitant feedback from the muscle stretch receptors for the control of the mammalian food-crushing bite force.
碾碎食物反射及其抑制作用
前牙(ANT)接触诱导短潜伏期反射抑制人类颌合肌。下颚是一个刚性的1级杠杆,用于精确地瞄准肌肉力量进入单个咬点,即旋转的食物颗粒。围绕食物颗粒支点的跷跷板反射运动增加了食物粉碎力。由食物碾碎引起的不可预测的反作用力的震动受到吻侧的ANT和尾侧的颚三角形的两个清晰的末端的影响。必须通过脱瘾反射来监测和抑制食物碾碎过程中的压缩/拉伸菌株。中脑神经节(Vmes)、神经髓鞘和肌肉拉伸受体随着下颚的出现而进化,以提高本体感觉和戒断反射的速度。在哺乳动物中,被食物支点拉伸的紧绷运动单元的纺锤体通过Vmes向各自同侧肌肉单元的传出神经元发送兴奋的单突触反馈。在Vmes中,纺锤体输入介导的传入神经元与来自后齿(BAT)机械感受器的另一个传入反馈源耦合,这也是兴奋性的。这两种兴奋性脉冲的来源是叠加的,并针对传出神经元来促进伸展和收缩的运动单元。同样,来自ANT机械感受器的传入反馈也在Vmes中与来自纺锤体的伴随反馈耦合。然而,蚂蚁输出抑制否定兴奋反馈从拉伸的颚肌单位。来自前牙的抑制性馈入暂时阻断咀嚼运动传出神经元的兴奋电位,以保护前牙和下颌关节免受无意的张力。来自前牙的抑制性输入与来自BAT的兴奋性输入交替进行,以确定在任何给定的食物碾碎时刻,哪个颌合肌单元被激活或被抑制。Vmes存在于所有有颌脊椎动物中,其进化可能是由控制咬合力的需求所驱动的。单突触单侧碾碎食物的兴奋性和抑制性反射(UFCRs)超越了共存的双侧中枢神经系统对颌骨肌肉的喂食。本研究提出的假设是,vvms介导的ufrs结合了来自牙齿接触的神经输入和来自肌肉拉伸受体的伴随反馈,以控制哺乳动物的咬合力。
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