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本文引用的文献

1
THE EFFECT OF ACETOACETATE ON OXYGEN CONSUMPTION OF BRAIN SLICES FROM INFANT AND ADULT RATS.乙酰乙酸对幼鼠和成年大鼠脑切片氧消耗的影响。
Physiol Bohemoslov (1956). 1965;14:134-6.
2
EFFECT OF ISCHEMIA ON KNOWN SUBSTRATES AND COFACTORS OF THE GLYCOLYTIC PATHWAY IN BRAIN.缺血对脑糖酵解途径已知底物和辅助因子的影响。
J Biol Chem. 1964 Jan;239:18-30.
3
The concentration of glucose in rat tissues.大鼠组织中葡萄糖的浓度。
Biochem J. 1956 Sep;64(1):145-50. doi: 10.1042/bj0640145.
4
Brain metabolism during fasting.禁食期间的脑代谢。
J Clin Invest. 1967 Oct;46(10):1589-95. doi: 10.1172/JCI105650.
5
Effects of fatty acids, ketone bodies, lactate and pyruvate on glucose utilization by guinea-pig cerebral cortex slices.脂肪酸、酮体、乳酸和丙酮酸对豚鼠大脑皮层切片葡萄糖利用的影响。
Biochem J. 1967 Aug;104(2):519-23. doi: 10.1042/bj1040519.
6
Metabolic interactions of glucose, lactate, and beta-hydroxybutyrate in rat brain slices.大鼠脑片中葡萄糖、乳酸和β-羟基丁酸的代谢相互作用
Am J Physiol. 1969 Sep;217(3):784-92. doi: 10.1152/ajplegacy.1969.217.3.784.
7
Glucose and lactic acid content of the rat brain.大鼠脑内葡萄糖和乳酸含量
J Neurochem. 1968 Feb;15(2):141-3. doi: 10.1111/j.1471-4159.1968.tb06185.x.
8
Acetoacetate metabolism in infant and adult rat brain in vitro.幼年和成年大鼠脑内乙酰乙酸代谢的体外研究
Biochem J. 1970 Feb;116(4):641-55. doi: 10.1042/bj1160641.
9
Activities of enzymes involved in acetoacetate utilization in adult mammalian tissues.成年哺乳动物组织中参与乙酰乙酸利用的酶的活性。
Biochem J. 1971 Jan;121(1):41-7. doi: 10.1042/bj1210041.
10
Activities of enzymes of ketone-body utilization in brain and other tissues of suckling rats.乳鼠大脑及其他组织中酮体利用酶的活性
Biochem J. 1971 Jan;121(1):49-53. doi: 10.1042/bj1210049.

成年和哺乳大鼠大脑在体内对酮体的利用

Ketone-body utilization by adult and suckling rat brain in vivo.

作者信息

Hawkins R A, Williamson D H, Krebs H A

出版信息

Biochem J. 1971 Mar;122(1):13-8. doi: 10.1042/bj1220013.

DOI:10.1042/bj1220013
PMID:5124783
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1176682/
Abstract
  1. Ketone-body utilization in fed and starved adult and suckling rats has been investigated by measuring arterio-venous differences across the brain. Venous blood was collected from the confluence of sinuses and arterial blood from the femoral artery in adult rats and by cardiac puncture in suckling rats. 2. During starvation the arterio-venous difference of ketone bodies increased in proportion to their concentrations in the blood and reached a value of 0.16mm at 48h. At a given concentration of the respective ketone bodies the arterio-venous differences of acetoacetate were about twice those of 3-hydroxybutyrate. 3. Fed rats in which the concentrations of ketone bodies were raised by intravenous infusion of sodium acetoacetate had the same arterio-venous differences as starved rats at corresponding ketone-body concentrations. Thus the ability of the rat brain to utilize ketone bodies is independent of the nutritional state. 4. The concentrations of glucose, acetoacetate and 3-hydroxybutyrate were much lower in the brain than in the arterial blood. The measured (blood concentration)/(brain concentration) ratio was 4.4 for glucose, 4.5 for acetoacetate and 8.1 for 3-hydroxybutyrate in 48h-starved rats. 5. The mean arterio-venous difference of glucose across the brain was 0.51mm in fed rats and 0.43mm in 96h-starved rats. 6. Conversion of glucose into lactate rose from negligible values in the fed state to 0.2mm after 48h starvation and decreased to zero after 96h starvation. 7. In 16-22-day-old suckling rats the arterio-venous differences of ketone bodies across the brain were also proportional to the ketone-body concentration, but they were about 3-4 times greater than in adult rats at the same blood ketone-body concentration. 8. Arterio-venous differences of glucose were about the same in adult and suckling rats. 9. The brain of fed suckling rats formed more lactate from glucose than fed adult rats. 10. The results indicate that ketone bodies are major metabolic fuels of the brain of the suckling rat under normal conditions.
摘要
  1. 通过测量成年和哺乳大鼠脑的动静脉差异,研究了喂食和饥饿状态下大鼠酮体的利用情况。成年大鼠从窦汇采集静脉血,从股动脉采集动脉血;哺乳大鼠则通过心脏穿刺采集血液。2. 在饥饿期间,酮体的动静脉差异随其在血液中的浓度成比例增加,48小时时达到0.16毫摩尔的值。在各自酮体的给定浓度下,乙酰乙酸的动静脉差异约为3-羟基丁酸的两倍。3. 通过静脉输注乙酰乙酸钠提高酮体浓度的喂食大鼠,在相应酮体浓度下与饥饿大鼠具有相同的动静脉差异。因此,大鼠脑利用酮体的能力与营养状态无关。4. 脑中葡萄糖、乙酰乙酸和3-羟基丁酸的浓度远低于动脉血中的浓度。在饥饿48小时的大鼠中,测得的(血液浓度)/(脑浓度)比值,葡萄糖为4.4,乙酰乙酸为4.5,3-羟基丁酸为8.1。5. 喂食大鼠脑的葡萄糖平均动静脉差异为0.51毫摩尔,饥饿96小时的大鼠为0.43毫摩尔。6. 葡萄糖转化为乳酸的量从喂食状态下可忽略不计的值,在饥饿48小时后升至0.2毫摩尔,饥饿96小时后降至零。7. 在16-22日龄的哺乳大鼠中,脑的酮体动静脉差异也与酮体浓度成正比,但在相同血液酮体浓度下,它们比成年大鼠大约高3-4倍。8. 成年大鼠和哺乳大鼠的葡萄糖动静脉差异大致相同。9. 喂食的哺乳大鼠脑从葡萄糖形成的乳酸比喂食的成年大鼠更多。10. 结果表明,在正常情况下,酮体是哺乳大鼠脑的主要代谢燃料。