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RISSThe salient pathological findings following acute blunt cord trauma, now documented by a number of investigators, are hemorrhagic necrosis of central gray matter and increased. catecholamine, especially dopamine concentration of the traumatized cord l...
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RISS 인기검색어
척수손상에 관한 실험적연구 : 제1보 : 개의 손상 척수백질의 K^(42) 섭취 Part Ⅰ: K^(42) Uptake of the Traumatized Canine Spinal Cord White Matter = Experimental Studies on the Spinal Cord Injury
한글로보기https://www.riss.kr/link?id=A40030909
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
1976
-
작성언어
Korean
-
KDC
510
-
등재정보
SCOPUS,SCIE,KCI등재
-
자료형태
학술저널
- 발행기관 URL
-
수록면
29-37(9쪽)
- 제공처
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
The salient pathological findings following acute blunt cord trauma, now documented by a number of investigators, are hemorrhagic necrosis of central gray matter and increased. catecholamine, especially dopamine concentration of the traumatized cord level, which have progressive and, according to some authors, reversible nature.
But paraplegia and disappearence of sensory evoked potential (SEP) are the obvious clinical conditions appeared immediately after blunt cord trauma which are sudden events not progressive ones. These phenomena are clearly results of neuronal conduction block of white matter at the traumatized cord level. Dohrmann et al. demonstrated in their electron microscopic studies that the myelinated nerve fibers of the traumatized cord level with 300 gm-㎝ force are resemble those of a control animal until 15 to 20 minutes after impact. At this point, we can imagine 2 phases of pathophysiological process of acute blunt cord trauma, ie;
1. Initial alterations of normal cord physiology.
2. Secondary or aggrevating processes to the initial alterations of normal physiology.
There are a number of reports and arguements about so called secondary aggrevating processes but neither explanations nor experimental studies about those immediate pathologic clinical phenomena.
As the initiation of the investigations about the immediate physiological alterations, we planned this experiment to observe radioactive potassium uptake of the white matter of the bluntly traumatized spinal cord.
At first, we carried dorsal laminectomy out on the T2 and T6 level of adult Mongoreal dogs and injected K^(42) Cl, 500 micro Ci into the right atrium via catheterized antecubital vein. At 6 seconds after injection of K^(42), 5cc bolus of saturated KCl was shot intravenously via same route to produce instant cardiac arrest. As rapidly as possible, the cord of T2 and T6 were excised and dissection of white matter was done which was facilitated by use of loupe. After tissue weighing, tissue indicator was counted with Well-type Scintillating Counter. As a result, the radioactivity of T6 white matter (cpm/mg) was 77% (SD=2.04) of that of T2, which was essentially same as the regional blood flow rates measured by Bingham et al. with fractional indicator technique.
Secondly, we elicited seizures on the animals by electrical stimuli delivered to the electrode attached on the bifrontal scalp. Seizure duration was 3 minutes and at the time of termination of tonic phase 500 micro Ci of K^(42) Cl was injected. 6 seconds later cardiac arrest was produced and radioactivity of the white matter of T2 and T6 were measured with same way described above. .Radioactive potassium uptake of the white. matter of T2 and T6 were 57.82% (SD=2.62) and 61.38% (SD=3.69) to those of control animal. This result can be explained as a greatly increased K^(+)ion concentration in the interstitial space of white matter during the convulsive seizure.
Next time, the animals were laminectomized on the level of T2 and T6, and 500 gm-㎝ force was impacted on the T6 exposed cord while T2 segment served as non-traumatized control. 15 minutes after impact, 500 micro Ci of K^(42) was injected and at 6 seconds after injection cardiac arrest was produced. And radioactivity of white matter was measured. The K^(42) uptake of the T6 white matter was 171%(SD=24) to that of T2, which was thought as a reflection of increases regional blood flow. Alteration of blood-brain barrier resistance must be influenced upon the K' ion uptake but they may be masked by increased blood flow, which was supported by a biphasic curve obtained from time-lag experiments, ie; decreased uptake in 1 1/2 hour group, increased uptake in 2 1/2 hour group and approach to the base line in the 4 hour group.
Another experimental study to discover so called immediate physiological changes will be presented in the next report.
But paraplegia and disappearence of sensory evoked potential (SEP) are the obvious clinical conditions appeared immediately after blunt cord trauma which are sudden events not progressive ones. These phenomena are clearly results of neuronal conduction block of white matter at the traumatized cord level. Dohrmann et al. demonstrated in their electron microscopic studies that the myelinated nerve fibers of the traumatized cord level with 300 gm-㎝ force are resemble those of a control animal until 15 to 20 minutes after impact. At this point, we can imagine 2 phases of pathophysiological process of acute blunt cord trauma, ie;
1. Initial alterations of normal cord physiology.
2. Secondary or aggrevating processes to the initial alterations of normal physiology.
There are a number of reports and arguements about so called secondary aggrevating processes but neither explanations nor experimental studies about those immediate pathologic clinical phenomena.
As the initiation of the investigations about the immediate physiological alterations, we planned this experiment to observe radioactive potassium uptake of the white matter of the bluntly traumatized spinal cord.
At first, we carried dorsal laminectomy out on the T2 and T6 level of adult Mongoreal dogs and injected K^(42) Cl, 500 micro Ci into the right atrium via catheterized antecubital vein. At 6 seconds after injection of K^(42), 5cc bolus of saturated KCl was shot intravenously via same route to produce instant cardiac arrest. As rapidly as possible, the cord of T2 and T6 were excised and dissection of white matter was done which was facilitated by use of loupe. After tissue weighing, tissue indicator was counted with Well-type Scintillating Counter. As a result, the radioactivity of T6 white matter (cpm/mg) was 77% (SD=2.04) of that of T2, which was essentially same as the regional blood flow rates measured by Bingham et al. with fractional indicator technique.
Secondly, we elicited seizures on the animals by electrical stimuli delivered to the electrode attached on the bifrontal scalp. Seizure duration was 3 minutes and at the time of termination of tonic phase 500 micro Ci of K^(42) Cl was injected. 6 seconds later cardiac arrest was produced and radioactivity of the white matter of T2 and T6 were measured with same way described above. .Radioactive potassium uptake of the white. matter of T2 and T6 were 57.82% (SD=2.62) and 61.38% (SD=3.69) to those of control animal. This result can be explained as a greatly increased K^(+)ion concentration in the interstitial space of white matter during the convulsive seizure.
Next time, the animals were laminectomized on the level of T2 and T6, and 500 gm-㎝ force was impacted on the T6 exposed cord while T2 segment served as non-traumatized control. 15 minutes after impact, 500 micro Ci of K^(42) was injected and at 6 seconds after injection cardiac arrest was produced. And radioactivity of white matter was measured. The K^(42) uptake of the T6 white matter was 171%(SD=24) to that of T2, which was thought as a reflection of increases regional blood flow. Alteration of blood-brain barrier resistance must be influenced upon the K' ion uptake but they may be masked by increased blood flow, which was supported by a biphasic curve obtained from time-lag experiments, ie; decreased uptake in 1 1/2 hour group, increased uptake in 2 1/2 hour group and approach to the base line in the 4 hour group.
Another experimental study to discover so called immediate physiological changes will be presented in the next report.
The salient pathological findings following acute blunt cord trauma, now documented by a number of investigators, are hemorrhagic necrosis of central gray matter and increased. catecholamine, especially dopamine concentration of the traumatized cord level, which have progressive and, according to some authors, reversible nature.
But paraplegia and disappearence of sensory evoked potential (SEP) are the obvious clinical conditions appeared immediately after blunt cord trauma which are sudden events not progressive ones. These phenomena are clearly results of neuronal conduction block of white matter at the traumatized cord level. Dohrmann et al. demonstrated in their electron microscopic studies that the myelinated nerve fibers of the traumatized cord level with 300 gm-㎝ force are resemble those of a control animal until 15 to 20 minutes after impact. At this point, we can imagine 2 phases of pathophysiological process of acute blunt cord trauma, ie;
1. Initial alterations of normal cord physiology.
2. Secondary or aggrevating processes to the initial alterations of normal physiology.
There are a number of reports and arguements about so called secondary aggrevating processes but neither explanations nor experimental studies about those immediate pathologic clinical phenomena.
As the initiation of the investigations about the immediate physiological alterations, we planned this experiment to observe radioactive potassium uptake of the white matter of the bluntly traumatized spinal cord.
At first, we carried dorsal laminectomy out on the T2 and T6 level of adult Mongoreal dogs and injected K^(42) Cl, 500 micro Ci into the right atrium via catheterized antecubital vein. At 6 seconds after injection of K^(42), 5cc bolus of saturated KCl was shot intravenously via same route to produce instant cardiac arrest. As rapidly as possible, the cord of T2 and T6 were excised and dissection of white matter was done which was facilitated by use of loupe. After tissue weighing, tissue indicator was counted with Well-type Scintillating Counter. As a result, the radioactivity of T6 white matter (cpm/mg) was 77% (SD=2.04) of that of T2, which was essentially same as the regional blood flow rates measured by Bingham et al. with fractional indicator technique.
Secondly, we elicited seizures on the animals by electrical stimuli delivered to the electrode attached on the bifrontal scalp. Seizure duration was 3 minutes and at the time of termination of tonic phase 500 micro Ci of K^(42) Cl was injected. 6 seconds later cardiac arrest was produced and radioactivity of the white matter of T2 and T6 were measured with same way described above. .Radioactive potassium uptake of the white. matter of T2 and T6 were 57.82% (SD=2.62) and 61.38% (SD=3.69) to those of control animal. This result can be explained as a greatly increased K^(+)ion concentration in the interstitial space of white matter during the convulsive seizure.
Next time, the animals were laminectomized on the level of T2 and T6, and 500 gm-㎝ force was impacted on the T6 exposed cord while T2 segment served as non-traumatized control. 15 minutes after impact, 500 micro Ci of K^(42) was injected and at 6 seconds after injection cardiac arrest was produced. And radioactivity of white matter was measured. The K^(42) uptake of the T6 white matter was 171%(SD=24) to that of T2, which was thought as a reflection of increases regional blood flow. Alteration of blood-brain barrier resistance must be influenced upon the K' ion uptake but they may be masked by increased blood flow, which was supported by a biphasic curve obtained from time-lag experiments, ie; decreased uptake in 1 1/2 hour group, increased uptake in 2 1/2 hour group and approach to the base line in the 4 hour group.
Another experimental study to discover so called immediate physiological changes will be presented in the next report.
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