실험적 뇌허혈증 모델에서 허혈 조직의 $^{99m}Tc$-glucarate 섭취

$^{99m}Tc$-Glucarate Uptake in Ischemic Tissue of Experimental Models of Cerebral Ischemia

허혈성 뇌 병변에서 $^{99m}Tc$-glucarate의 섭취에 관한 연구를 하기 위하여 중뇌동맥 폐쇄 쥐 뇌허혈 모델을 재관류한 군과 하지 않은 군으로 나누어 만들었다. $^{99m}Tc$-glucarate와 [$^{18}F$]FDG를 연속적으로 투여하여 그 분포 양상을 이중 자가방사촬영법으로 관찰하였다. 조직의 괴사 여부를 알기 위하여 TTC 염색도 실시하여 동일한 뇌표본에 대하여 3가지의 영상을 동시에 얻을 수가 있었다. 얻은 영상으로 섭취 또는 비섭취정도를 보아 0점에서 3점까지 점수를 매겨 합하여 비교하였다. 수술한 쥐들 18마리 중 10마리가 신경학적 증상을 보이면서 살아남아 실험대상이 되었다. TTC 염색으로 확인한 경색크기는 재관류하지 않은 군이 컸다. [$^{18}F$]FDG 섭취양상은 TTC 염색과 거의 비슷하였다. 다만 일부에서 TTC 염색되는 곳에 [$^{18}F$]FDG 가 중간정도로 섭취되는 곳이 있었고 TTC 염색되지 않는 곳에 [$^{18}F$]FDG가 중간정도 섭취되는 곳이 있었다. TTC로 염색된 부위에는 $^{99m}Tc$-glucarate가 섭취되지 않았다. TTC로 염색되지 않는 곳에 일부분 $^{99m}Tc$-glucarate가 섭취되었다. TTC와 [$^{18}F$]FDG가 염색되거나 섭취되지 않는 곳에 $^{99m}Tc$-glucarate가 섭취되지 않는 곳이 있었다. 그러나 [$^{18}F$]FDG의 중간 정도의 섭취나 [$^{18}F$]FDG와 TTC사이에 부합하지 않는 곳 등과 $^{99m}Tc$-glucarate 섭취와 대응시키기 어려웠다 $^{99m}Tc$-glucarate가 재관류 군에서 더 넓고 많이 섭취되었다. 결론적으로 $^{99m}Tc$-glucarate는 비생존 허혈조직에만 섭취되는데 관류재개통에 따라 다양하게 섭취되었고 재관류모델에 더 많이 넓게 섭취되었다. 중뇌동맥폐색 및 재관류 모델로 $^{99m}Tc,\;^{18}F$ 및 TTC 동시영상을 얻어 생존능과 포도당대사의 부합 비부합 여부를 밝히고 그 의의를 조사한 후 $^{99m}Tc$-glucarate섭취와 상관을 조사하면 $^{99m}Tc$-glucarate섭취의 의의를 밝힐 수 있을 것으로 본다.

To detect ischemic tissue in experimental model of cerebral ischemia made by middle cerebral artery(MCA)-occlusion, we acquired triple image of $^{99m}Tc$-glucarate, [$^{18}F$]fluoro-deoxyglucose (FDG), and 2,3,5- triphenyltetrazolium (TTC) staining. We made cerebral infarction either with reperfusion (after occlusion of 2 hours) or without reperfusion in 10 Sprague-Dawley rats by inserting thread to MCA through internal carotid artery. After 22 hours, we injected 740 MBq of $^{99m}Tc$-glucarate and 55.5 MBq of [$^{18}F$]FDG through tail vein. Each 1 mm slice of rat brains was frozen and exposed to imaging plate for 20 minutes in freezer to get an [$^{18}F$]FDG image. After 20 hours enough to fade radioactivity of [$^{18}F$]FDG, the slices were again imaged by BAS1500 for $^{99m}Tc$-glucarate uptake. Finally, these brain tissues were stained with TTC. Semi-quantitative visual analysis was done by grading 0 to 3 points according to the degree of uptakes($^{99m}Tc$-glucarate) and decreased uptakes([$^{18}F$]FDG and TTC). Ten rats survived with neurologic symptoms. TTC staining confirmed the development of infarction. The size of the infarction was relatively larger in the group without reperfusion. [$^{18}F$]FDG images were similar to TTC-stained images. However, we found regions with intermediate uptake which were not stained with TTC. We found regions with intermediate [$^{18}F$]FDG uptake where TTC staining was normal. $^{99m}Tc$-glucarate uptake was round only in TTC non-stained region. In the TTC stained regions, there were no uptake of $^{99m}Tc$-glucarate. We could not find clear relation between $^{99m}Tc$-glucarate uptake with [$^{18}F$]FDG uptake. This was partly because percent uptake of $^{99m}Tc$-glucarate was so small (less than 1 percent of injected dose) and because there were quite heterogeneity of patterns of [$^{18}F$]FDG uptake and TTC. With these findings, we could conclude that $^{99m}Tc$-glucarate were taken up only in part of ischemic tissues which were proven to be nonviable. The establishment of MCA-occluded rat model with or without reperfusion and triple imaging for $^{99m}Tc,\;^{18}F$ and TTC helped the characterization of $^{99m}Tc$-glucarate uptakes. Further work is needed to clarify the meaning or diversities or [$^{18}F$]FDG and TTC and their relation with $^{99m}Tc$-glucarate.