Jeevanandam M, Holaday N J, Petersen S R
Trauma Center, St. Joseph's Hospital and Medical Center, Phoenix, Arizona 85013, USA.
Nutrition. 1996 Nov-Dec;12(11-12):777-87. doi: 10.1016/s0899-9007(96)00220-1.
An anabolic stimulus is needed in addition to conventional nutritional support in the catabolic "flow" phase of severe trauma. One promising therapy appears to be rhGH infusion which has direct as well as hormonal mediated substrate effects. We investigated on a whole-body level, the basic metabolic effects of trauma within 48-60 h after injury in 20 severely injured (injury severity score [ISS] = 31 +/- 2), highly catabolic (N loss = 19 +/- 2 g/d), hypermetabolic (resting energy expenditure [REE] = 141 +/- 5% basal energy expenditure [BEE]), adult (age 46 +/- 5 y) multiple-trauma victims, before starting nutrition therapy and its modification after 1 wk of rhGH supplementation with TPN (1.1 x REE calories, 250 mg N.kg-1.d-1). Group H (n = 10) randomly received at 8:00 a.m. on a daily basis rhGH (0.15 mg.kg-1.d-1) and Group C (n = 10) received the vehicle of infusion. Protein metabolism (turnover, synthesis and breakdown rates, and N balance); glucose kinetics (production, oxidation, and recycling); lipid metabolism, (lipolysis and fat oxidation rates), daily metabolic and fuel substrate oxidation rate (indirect calorimetry); and plasma levels of hormones, substrates, and amino acids were quantified. In group H compared to group C: N balance is less negative (-41 +/- 18 vs -121 +/- 19 mg N.kg-1.d-1, P = 0.001); whole body protein synthesis rate is 28 +/- 2% (P = 0.05) higher; protein synthesis efficiency is higher (62 +/- 2% vs 48 +/- 3%, P = 0.010); plasma glucose level is significantly elevated (256 +/- 25 vs 202 +/- 17 mg/dL, P = 0.05) without affecting hepatic glucose output (1.51 +/- 0.20 vs 1.56 +/- 0.6 mg N.kg-1.min-1), glucose oxidation and recycling rates; significantly enhanced rate of lipolysis (P = 0.006) and free fatty acid reesterification (P = 0.05); significantly elevated plasma levels of anabolic GH, IGF-1, IGFBP-3, and insulin; trauma induced counter-regulatory hormone (cortisol, glucagon, catecholamines) levels are not altered; trauma induced hypoaminoacidemia is normalized (P < 0.05) and 3-methylhistidine excretion is significantly low (P < 0.001). Improved plasma IGF-1 levels in Group H compared with Group C account for protein anabolic effects of adjuvant rhGH and may be helpful in promoting tissue repair and early recovery. Skeletal muscle protein is spared by rhGH resulting in the stimulation of visceral protein breakdown. The hyperglycemic, hyperinsulinemia observed during rhGH supplementation may be due to defective nonoxidative glucose disposal, as well as inhibition of glucose transport activity into tissue cells. The simultaneous operation of increased lipolytic and reesterification processes may allow the adipocyte to respond rapidly to changes in peripheral metabolic fuel requirements during injury. This integral approach helps us to better understand the mechanism of the metabolic effects of rhGH.
在严重创伤的分解代谢“流动”阶段,除了传统的营养支持外,还需要一种合成代谢刺激。一种有前景的治疗方法似乎是注射重组人生长激素(rhGH),它具有直接以及激素介导的底物效应。我们在全身水平上,研究了20名严重受伤(损伤严重度评分[ISS]=31±2)、高分解代谢(氮丢失=19±2 g/d)、高代谢(静息能量消耗[REE]=基础能量消耗[BEE]的141±5%)的成年(年龄46±5岁)多发伤患者在受伤后48 - 60小时内创伤的基本代谢效应,在开始营养治疗前以及在rhGH补充1周并联合全胃肠外营养(1.1×REE卡路里,250 mg N·kg⁻¹·d⁻¹)后的代谢变化。H组(n = 10)每天上午8点随机接受rhGH(0.15 mg·kg⁻¹·d⁻¹),C组(n = 10)接受输液载体。对蛋白质代谢(周转率、合成和分解率以及氮平衡);葡萄糖动力学(生成、氧化和再循环);脂质代谢(脂解和脂肪氧化率)、每日代谢和燃料底物氧化率(间接测热法);以及激素、底物和氨基酸的血浆水平进行了量化。与C组相比,H组:氮平衡的负值更小(-41±18 vs -121±19 mg N·kg⁻¹·d⁻¹,P = 0.001);全身蛋白质合成率高28±2%(P = 0.05);蛋白质合成效率更高(62±2% vs 48±3%,P = 0.010);血浆葡萄糖水平显著升高(256±25 vs 202±17 mg/dL,P = 0.05),但不影响肝脏葡萄糖输出(1.51±0.20 vs 1.56±0.6 mg N·kg⁻¹·min⁻¹)、葡萄糖氧化和再循环率;脂解率(P = 0.006)和游离脂肪酸再酯化率显著提高(P = 0.05);合成代谢的生长激素、胰岛素样生长因子-1(IGF-1)、胰岛素样生长因子结合蛋白-3(IGFBP-3)和胰岛素的血浆水平显著升高;创伤诱导的反调节激素(皮质醇、胰高血糖素、儿茶酚胺)水平未改变;创伤诱导的低氨基酸血症恢复正常(P < 0.05),3 - 甲基组氨酸排泄显著降低(P < 0.001)。与C组相比,H组血浆IGF-1水平的改善解释了辅助rhGH的蛋白质合成代谢作用,可能有助于促进组织修复和早期恢复。rhGH使骨骼肌蛋白质得以保留,从而刺激内脏蛋白质分解。补充rhGH期间观察到的高血糖、高胰岛素血症可能是由于非氧化葡萄糖处理缺陷以及组织细胞葡萄糖转运活性受到抑制。脂解和再酯化过程同时增强,可能使脂肪细胞在损伤期间能够快速响应外周代谢燃料需求的变化。这种综合方法有助于我们更好地理解rhGH代谢效应的机制。
