A Modified Technique to Harvest Integrated Zygomatic Arch-Temporal Bone Flap: Clinical Experience.

Background: In skull base surgery, zygomaticectomy is an effective method to increase surgical exposure and reduce brain retraction. However, the traditional zygomaticectomy methods are complicated and more invasive. Objective: To improve the procedure of zygomaticectomy, we introduced a modified technique to harvest integrated zygomatic arch-temporal bone flap. Subjects and Methods: A modified technique to section the zygomatic arch integrated with the temporal bone flap was described in the present work. This technique was applied in eight skull base lesion patients. The improved surgical angle was measured using Osirix software. Results: The surgical exposure is satisfied and no temporal lobe contusion or severe complications occurred in the patients. An increased surgical angle was obtained by zygomatic arch removing, with a mean value of 13.31°. Conclusions: This integrated zygomatic arch-temporal bone flap technique achieved increased exposure, decreased temporal lobe retraction, and minimal bone loss, leading to better cosmetics and functional reconstructions.

Acrolein Induces Systemic Coagulopathy via Autophagy-dependent Secretion of von Willebrand Factor in Mice after Traumatic Brain Injury / 神经科学通报·英文版

Traumatic brain injury (TBI)-induced coagulopathy has increasingly been recognized as a significant risk factor for poor outcomes, but the pathogenesis remains poorly understood. In this study, we aimed to investigate the causal role of acrolein, a typical lipid peroxidation product, in TBI-induced coagulopathy, and further explore the underlying molecular mechanisms. We found that the level of plasma acrolein in TBI patients suffering from coagulopathy was higher than that in those without coagulopathy. Using a controlled cortical impact mouse model, we demonstrated that the acrolein scavenger phenelzine prevented TBI-induced coagulopathy and recombinant ADAMTS-13 prevented acrolein-induced coagulopathy by cleaving von Willebrand factor (VWF). Our results showed that acrolein may contribute to an early hypercoagulable state after TBI by regulating VWF secretion. mRNA sequencing (mRNA-seq) and transcriptome analysis indicated that acrolein over-activated autophagy, and subsequent experiments revealed that acrolein activated autophagy partly by regulating the Akt/mTOR pathway. In addition, we demonstrated that acrolein was produced in the perilesional cortex, affected endothelial cell integrity, and disrupted the blood-brain barrier. In conclusion, in this study we uncovered a novel pro-coagulant effect of acrolein that may contribute to TBI-induced coagulopathy and vascular leakage, providing an alternative therapeutic target.

Establishment of A Model in Rat Brain Nuclei Microelectrode Recording Coupled Behavioristics for Rehabilitation Experiment / 中国康复理论与实践

@#Objective To establish a coupled model combining the rat brain nuclei microelectrode recordings and the behavioristics for rehabilitation experiment. Methods The modified indwelling tube connection fixed device was put inside the rats' back, and the microprobes were implanted into related neural nucleus. A signal connection was made between self-administration system and electrophysiological data acquisition system. The rat was addicted after training by self-administration system. The related cerebral nucleus electrophysiological sig-nals were recorded in different states of addiction. Results and Conclusion The modified indwelling tube connection fixed device has a bet-ter quality for reducing the phenomenon of leak. The signal was well in the combination of two different systems. The signals for the rat's ac-tion and neural electrical were recorded in the same time.

THE EXPRESSION OF FOS IN THE WHOLE BRAIN OF RATS FOLLOWING COMPLEX DOUBLE ROTATION ON TWO AXES / 神经解剖学杂志

To investigate the relationship of the rotation stimulation with motion sickness, the expression of Fos protein in the whole brain of the rat stimulated by complex double rotation on two axes was observed in the present study. The rats were randomly divided into four groups: normal contral group; double-axes rotation stimulation group; the bilateral labyrinthectomy group; group of two-axes rotation stimulation after the bilateral labyrinthectomy. Immunohistochemical staining method was used to detect the expression of Fos protein in different regions of whole brain of the rat. The present results showed that: (1) No Fos-like immunoreactivity was detected in the brain of the rats in control group and the bilateral labyrinthectomy group; (2) In the double-axes rotation stimulation group, the Fos-like immunoreactive neurons were observed in many regions of the brain and brainstem of the rats following complex double-axes rotation stimulation, and the Fos-immunoreactivities were expressed in the nucleus. These Fos-immunopositive neurons were intensively distributed in different subnuclei of the vestibular nucleus complex (including medial, superior and spinal nuclei), nucleus of the solitary tract, locus coeruleus, medial and lateral parabrachial nucleus of the brainstem, paraventricular nucleus of the diencephalons and the amygdala of the limbic system; (3) The expression of Fos protein can be scarcely detected around forementioned regions in brains of the rats following complex two-axes rotation stimulation after the bilateral labyrinthectomy. The present results suggest that the double-axes rotation stimulation can activate effectively the vestibular neurons and many neurons of other region of the brain and brainstem are further activated through direct or indirect connections with vestibular nuclei after complex double rotation stimulation. These activated neurons may be related to the complex mechanism of the motion sickness.