hin Med J (Engl).2012;125(24):4328-33.7Nachimuthu DSj Baladhandapani A.Multidimens1nal TextureCharacterizat1n: On
Analysis for Brain Tumor Tissues Using MRS and MR1.J Digit Imaging.2014Feb 5.8Guo Jj Yao C,Chen H,Zhuang D,Tang Wj Ren G,Wang Y,Wu J,Huang F,Zhou
L.The relat1nship between Cho/NAA and gl1ma metabolism:1mplementat1n formargin
delineat1n of cerebral gl1mas.Acta Neurochir (Wien).2012;154(8):1361-70; discuss1n 1370.9Esmaeili M, Vettukattil R, Bathen TF.2-hydroxyglutarate as a magneticresonance b1marker for gl1ma subtyping.Transl Oncol.2013;6 (2):92-8.10Krafft Cj Sobottka SB, Schackert G, Salzer R.Raman and infraredspectroscopic mapping of human primary intracranial tumors: a comparativestudy.J Raman Spectrosc 2006;37:367 - 375.11Koljenovi S, Choo-Smith LPj Bakker Schut TC, et al.Discriminatingvital tumor from necrotic tissue in human gl1blastoma tissue samples by Ramanspectroscopy.Lab Invest.2002;82 (10):1265-77.12Ji Mj Orringer DAj Freudiger Cffj Ramkissoon S, et al.Rapid, label-freedetect1n of brain tumors with stimulated Raman scattering microscopy.SciTransl Med.2013; 5 (201): 201rall9.13Leslie DGj Kast RE,Poulik JMj et al.1dentificat1n of pediatric brainneoplasms using Raman spectroscopy.Pediatr Neurosurg.2012;48 (2):109-17.14Bergner N,Krafft C,Geiger KDj Kirsch M,Schackert G,Popp J.Unsupervised
unmixing of Raman microspectroscopic images for morphochemical analysis ofnon-dried brain tumor specimens.Anal B1anal Chem.2012;403 (3):719-25.15Beleites C,Geiger K,Kirsch M,Sobottka SB,Schackert G,Salzer R.Raman
spectroscopic grading of astrocytoma tissues: using soft reference
informat1n.Anal B1anal Chem.2011:400(9):2801-16. 16Beljebbar A,Dukic S,Amharref N,Manfait M.Ex vivo and in vivodiagnosis of
C6 gl1blastoma development by Raman spectroscopy coupled to a microprobe.Anal
B1anal Chem.2010:398(1):477-87.17Amharref N, Beljebbar A, Dukic S, Venteo L, Schneider L, Pluot M, Manfait
M.Discriminating healthy from tumor and necrosis tissue in rat brain tissuesamples
by Raman spectral imaging.B1chim B1phys Acta.2007;1768 (10):2605-15.18Kalkanis SN, Kast RE, Rosenblum ML, et al.Raman spectroscopy todistinguish grey
matter, necrosis, and gl1blastoma multiforme in frozen tissue sect1ns.JNeurooncol.2014;116 (3):477-85.19Diaz RJj McVeigh PZj O’Reilly MAj Burrell K,Bebenek M,Smith C,Etame
ABj
Zadeh G, Hynynen K, Wilson BCj Rutka JT.Focused ultrasound delivery ofRaman
nanoparticles across the blood—brain barrier: Potential for targetingexperimental brain tumors.Nanomedicine.2013 Dec 27.。
【发明内容】
[0008]本发明的目的在于提供一种一体化脑胶质瘤手术器械,具体涉及一种⑶SA-RamanSpectra—体化脑胶质瘤手术器械;该手术器械在术中切除肿瘤的同时,能实时判定肿瘤性质的功能,可用于确定肿瘤切除的范围,以达到预期手术效果。
[0009]成洞超声波手术吸引器(cavitat1nalultrasonic surgical aspirat1n,CUSA)是脑胶质瘤手术常用的手术器械,通过超声波震碎胶质瘤组织后直接吸出,从而达到切除胶质瘤的作用。所述CUSA最前端为超声刀头,两边各有一个侧孔,一处为喷水口,用于降温和冲洗破碎胶质瘤组织,一处为吸引,直接吸出混在在水中的胶质瘤匀浆。
[0010]本申请在⑶SA的基础上进行改进,提供了命名为⑶SA-Raman Spectra 一体化手术器械,保留CUSA原有结构,在吸引通路上分出一路用于收集产生的胶质瘤匀浆,使用光纤直接连接到便携式拉曼光谱分析仪上(如图1所示),实现一边切除肿瘤,一边分析切除部位肿瘤Cho和NAA的拉曼特性,得到实时Cho/NAA的比值和2-HG信息,判断切除是否达到了细胞层面乃至分子层面的全部切除,从而有效提高脑胶质瘤患者的手术效果,改善总体预后,配合放化疗手段,有望根治低级别胶质瘤、延缓高级别胶质瘤的复发,具有极大的医疗价值和社会意义,同时具备广泛的产业化前景。
[0011]具体而言,本发明的⑶SA-Raman Spectra—体化脑胶质瘤手术器械,其特征在于,由超声刀1、样本盒2、拉曼光谱仪3、连接装置4、负压吸引器5组成;所述超声刀I通过连接装置4与样本盒2相连接,该样本盒2固定于拉曼光谱仪3的载物台上、同时又与负压吸引器5相连接。
[0012]本发明中,所述装置中超声刀1、拉曼光谱仪3、负压吸引器5均为已有在产设备;所述样本盒2采用硅材料制备,以减少拉曼峰的干扰;所述连接装置4通常采用工程塑料、PVC塑料等高分子材料制备;
本发明中,所述样本盒2为娃制透明立方体容器,其外形尺寸为40mmX30mmX 10mm、容器壁厚Imm ;所述样本盒中央设一个观察孔凹槽,用于拉曼激发光源的射入,所述观察孔凹槽的尺寸为5mmX 5mmX 7mm ;该样本盒的一个侧壁的外形尺寸为30mmX 10mm,其上设有2处相离的圆孔并伸出通道,该通道长度20mm、内径8mm、外径10mm,其中,上述一处通道与所述负压吸引器5相连接,另一处通道与所述连接装置4相连接;
本发明中,所述连接装置4用于连接超声