常规肺功能与肺胺代谢功能初步探讨

本文报告了36例研究对象肺廓清~(131)I-三甲基羟基-间碘-苯二胺(~(131)I-HIPDM)结果,其中31例作了常规肺功能及动脉血气检查。结果表明不同组间肺廓清~(131)I-HIPDM速率不同,能形成一个新的肺功能障碍指数。右肺廓清~(131)I-HIPDM快相与用力肺活量(FVC)、第1秒用力呼气量(FEV_1)、功能残气量(FRC)、残气量(RV)肺总量(TLC)相关P<0.01;与最大呼气流量(PEFR)、肺活量(VC)、最大通气量(MVV)、动脉血氧分压(PaO_2)相关P<0.05。肺廓清~(131)I—HIPDM速率反映了肺功能状态,对疾病分期及早期肺功能损伤检测优于常规肺功能。     

四君子汤对烧伤豚鼠早期代谢营养的影响

为探讨四君子汤对烧伤早期代谢营养的作用，采用３０％Ⅲ度烧伤豚鼠胃造口模型将４００ｇ左右豚鼠分别在喂养等量热卡、氮和自由进食两种膳食条件下，将３１只豚鼠分为四组，即喂养治疗组（ｎ＝７），喂养对照组（ｎ＝４），自食治疗组（ｎ＝９），自食对照组（ｎ＝１１）予以观察。结果发现：自由进食时，四君子汤能增加摄食量，减轻伤后体重丢失，改善氮平衡，增加肝、回肠粘膜含氮量，而躯壳重及腓肠肌含氮量增加不明显，但静息代谢率则增加；等量喂养时，四君子汤治疗组体重、躯壳重及腓肠肌含氮量显著低于对照组，而肝、肠粘膜重量及含氮量差异无显著意义。此外，四君子汤还可调整激素和内脏组织含水量。因此，我们认为四君子汤对改善烧伤后代谢营养及脏器功能可能是有益的     

模拟缺血再灌注后心肌细胞的胰岛素抵抗现象

目的准确评价缺血再灌注心肌的胰岛素敏感性及其时相规律，为临床干预提供依据。方法建立成年大鼠心肌细胞模拟缺血60min再灌注模型，应用同位素示踪技术观察不同浓度（0IU／L、0．01IU／L、20IU／L）胰岛素刺激大鼠心肌细胞的葡萄糖摄取效应。结果缺血60min后再灌注15min和60min，心肌细胞活性比率无明显降低（P〉0．05）。胰岛素能促进各组心肌细胞的葡萄糖摄取，并呈剂量依赖性。缺血再灌注15min组和再灌注60min组心肌细胞胰岛素刺激的葡萄糖摄取较对照组均明显降低（P〈0．05）。再灌注60min组心肌细胞胰岛素刺激的葡萄糖摄取较再灌注15min组明显增加（P〈0．05）。结论缺血60min后，再灌注心肌细胞保留了对胰岛素的反应性，同时，再灌注心肌细胞发生明显的急性胰岛素抵抗，再灌注初期尤为严重。急性胰岛素抵抗很可能是缺血再灌注心肌损伤的又一重要机制。     

VEGF165cDNA治疗缺血心肌的实验研究

目的：观察VEGFl65cDNA治疗缺血心肌后心功能、血流动力学、心肌灌注和代谢的变化。方法：健康杂种犬36只，随机分为VEGFl65cDNA和空质粒(pcDNA3：1)组(n＝12)，心肌梗塞组为对照组。Amroid环致慢性心肌缺血模型。VEGFl65基因转染采用直接心肌注射法。结果：基因转染后4周、8周时VEGF165基因组LVEF和CO及前壁、前侧壁、前间壁心肌灌注量、代谢和FDG摄入量明显高于同期心肌梗塞组。结论：VEGFl65基因治疗后4周和8周时心功能显著改善；成活心肌的数量显著增加和/或称成活心肌功能显著恢复。     

Trichloroethanol is not a metabolite of alpha chloralose

Head space capillary gas chromatography was used to detect alpha chloralose and its potent metabolite, trichloroethanol in clinical and forensic cases. Although alpha chloralose was identified in blood and urine in all cases, trichloroethanol was never detected. In a fatal case the alpha chloralose concentration in blood was 151.3 mg/l. It was concluded that trichloroethanol is not a metabolite of alpha chloralose.     

Tissue distribution metabolism and excretion of 2,2′,4,4′, 5-pentachlorodiphenyl ether in the rat

The tissue distribution, metabolism and excretion of ¹⁴C-2,2,4,4,5-pentachlorodiphenyl ether (PCDE) were studied in the rat. Radioactivity was distributed in all tissues examined, with the highest concentrations being found in the fat followed by the skin, liver, kidney and muscle. Most of the radioactivity found in the tissues was due to unchanged PCDE. Decay of PCDE in the blood was fitted to a four-compartment pharmacokinetic model, and the last compartment had a half-life of 5.8 days. A total of 55% and 1.3% of an orally administered dose was excreted in feces and urine, respectively, in 7 days. More than 64% of the fecal radioactivity was due to unchanged PCDE, while hydroxylated PCDE accounted for 23%.     

Fifty years of research onN-acetyl-2-aminofluorene,one of the most versatile compounds in experimental cancer research

Summary It is just about 50 years since the publication of the report on the toxicity and carcinogenicity of the potent carcinogenN-acetyl-2-aminofluorene (AAF). In 1940 very few reports on the carcinogenic activity of chemical compounds in experimental animals were available. The discovery of pure chemicals as carcinogens, such as AAF, azo dyes and benzo[a]pyrene, provided cancer researchers with a number of tools whereby the progressive changes involved in the induction of cancer could be studied in experimental systems. Contrary to the results with other carcinogens then known, AAF induced numerous types of tumors, but not at the site of application. This finding stimulated a great deal of interest in its use as an experimental carcinogen to study its metabolic fate and mechanism of action. During the following years an ever increasing number of reports appeared on the carcinogenicity of AAF in various species, on its metabolic fate, on the interaction of reactive metabolites with nucleic acids and proteins, and on its mutagenic activity. Particularly studies on the metabolism of AAF and the interaction with nucleic acids have contributed appreciably to our understanding of the mechanism of action of aromatic amines and also of other chemical carcinogens. It can be expected that AAF and its derivatives will continue to be used for specific applications in experimental cancer research. One of the most recent achievements is the preparation of site-specific AAF- and aminofluorene-modified DNA sequences for mutagenesis studies.Abbreviation AAF N-acetyl-2-aminofluorenem The Journal of Cancer Research and Clinical Oncology publishes in loose succession Editorials and Guest editorials on current and/or controversial problems in experimental and clinical oncology. These contributions represent exclusively the personal opinion of the author The Editors     

Functional compartmentalization of energy production in neural tissue

Previous work in our laboratory has shown that neural trauma results in a disparity between oxidative and glycolytic rates. In non-neural tissue, glycolysis and oxidative phosphorylation have been shown to work independently of one another, a phenomenon known as "energy compartmentalization". We believe that functional compartmentalization of energy production may also occur in the brain with glycolysis providing energy for membrane bound ionic pumps. Spreading depression, induced in rodent brain by topical KCl application, results in K+ shifts. The restoration of K+ gradients is accomplished by energy dependent Na(+)-K+ pumps. If these pumps depend upon glycolysis, blocking glycolysis should prevent reconstitution of normal [K+]e levels. The present series of experiments were designed to suggest that energy compartmentalization may also exist in brain, and that glycolytic energy production is preferentially used by Na(+)-K+ pumps to maintain normal ionic homeostasis by observing the dynamics of spreading depression induced K+ shifts before and after glycolytic blockade. Spreading depression was associated with increased K+ (48.6 +/- 16.6 mM over control) that normalized within 2.9 +/- 0.3 minutes. Following superfusion with a glycolytic blocking agent, spreading depression produced similar increases in [K+]e (40.6 +/- 12.0 mM over control) but time for reconstitution of the normal [K+]e was 400% longer than controls (2.9 +/- 0.3 to 14.9 +/- 2.1 minutes, P less than 0.001). Time required for recovery of EEG was identical pre- and post-blockade. We believe these data suggest that energy compartmentalization may exist in neural tissue and that glycolytic pathways of energy production are functionally tied to membrane Na(+)-K+ pumps.(ABSTRACT TRUNCATED AT 250 WORDS)     

Muscle and liver glycogen,protein, and triglyceride in the rat

Summary We have previously found that during exercise net muscle glycogen breakdown is impaired in adrenodemedullated rats, as compared with controls. The present study was carried out to elucidate whether, in rats with deficiencies of the sympatho-adrenal system, diminished exercise-induced glycogenolysis in skeletal muscle was accompanied by increased breakdown of triglyceride and/or protein. Thus, the effect of exhausting swimming and of running on concentrations of glycogen, protein, and triglyceride in skeletal muscle and liver were studied in rats with and without deficiencies of the sympatho-adrenal system. In control rats, both swimming and running decreased the concentration of glycogen in fast-twitch red and slow-twitch red muscle whereas concentrations of protein and triglyceride did not decrease. In the liver, swimming depleted glycogen stores but protein and triglyceride concentrations did not decrease. In exercising rats, muscle glycogen breakdown was impaired by adrenodemedullation and restored by infusion of epinephrine. However, impaired glycogen breakdown during exercise was not accompanied by a significant net breakdown of protein or triglyceride. Surgical sympathectomy of the muscles did not influence muscle substrate concentrations. The results indicate that when glycogenolysis in exercising muscle is impeded by adrenodemedullation no compensatory increase in breakdown of triglyceride and protein in muscle or liver takes place. Thus, indirect evidence suggests that, in exercising adrenodemedullated rats, fatty acids from adipose tissue were burnt instead of muscle glycogen.     

Influence of glucose ingestion by humans during recovery from exercise on substrate utilisation during subsequent exercise in a warm environment

Carbohydrate (CHO) ingestion during short-term recovery from prolonged running has been shown to increase the capacity for subsequent exercise in a warm environment. The aim of this study was to examine the effects of the amount of glucose given during recovery on substrate storage and utilisation during recovery and subsequent exercise in a warm environment. A group of 11 healthy male volunteers took part in two experiments in a controlled warm environment (35°C, 40% relative humidity), 1 week apart. On each occasion the subjects completed two treadmill runs (T1 and T2) at a speed equivalent to 60% of maximal oxygen uptake, for 90 min, until they were fatigued, or until aural temperature (T _aur) reached 39°C. The two runs were separated by a 4 h recovery period (REC), during which subjects consumed 55 g of naturally enriched [U-¹³C]-glucose in the form of a 7.5% carbohydrate-electrolyte solution (CES, mass of solution 667 g) immediately after T1. The subjects then consumed either: the same quantity of CES, or an equivalent volume of an electrolyte placebo, at 60, 120 and 180 min during REC, providing a total of 220 g (C220) or 55 g (C55) of [U-¹³C]-glucose, respectively. Expired gases were collected at 15 min intervals during exercise and 60 min intervals during REC, for determination of total CHO and fat oxidation by indirect respiratory calorimetry, and orally ingested [U-¹³C]-glucose oxidation, estimated from the ¹³C:¹²C ratio of expired CO₂. Substrate metabolism did not differ between conditions during T1. Despite the fact that total CHO (P<0.05) and ingested glucose oxidation (P<0.01) were greater during REC of the C220 condition, glycogen synthesis was estimated to be approximately fivefold greater (P<0.01) than in the C55 condition. During T2 the rate of total CHO oxidation was higher (P<0.01) and total fat oxidation lower (P<0.01) at all times during the C220 compared to the C55 condition. The greater CHO oxidation during C220 appeared to be met from ingested sources, as the rate of [U-¹³C]-glucose oxidation was greater (P<0.01) at all times during T2, compared to C55. Whilst more of the ingested substrate remained unoxidised on completion of T2 during C220, exercise duration was similar in the two experimental conditions, and was limited by thermoregulatory incapacity (T _aur>39°C) rather than substrate availability per se. Electronic Publication