CAJ | 학술논문

目的探讨胎儿生长受限(fetal growth restriction,FGR)大鼠胰岛素敏感性的变化规律.方法母鼠受孕后第1天始随机分为对照组和低蛋白组,各10只.低蛋白组孕鼠采用低蛋白饮食法建立FGR模型.低蛋白组仔鼠中出生体重低于对照组仔鼠平均出生体重两个标准差者定为FGR鼠.测定对照组和FGR仔鼠(每组雌雄各8只)生后3、7、14、30、60及90 d空腹血浆血糖(fasting plasma glucose,FPG)及空腹血清胰岛索(fasting serum insulin,FINS),计算胰岛素抵抗指数及胰岛素敏感指数.90 d时测定血甘油三酯、低密度脂蛋白胆固醇、高密度脂蛋白胆固醇和糖化血红蛋白,同时行腹腔葡萄糖耐量实验.结果 (1)低蛋白组仔鼠平均出生体重为(4.92±0.36)g,低于对照组的(6.43±0.59)g,差异有统计学意义(t=14.73,P＜0.05).(2)雄性FGR鼠生后60 d时FPG高于对照组[(9.38±1.57)mmol/L与(5.58士1.24)mmol/L],直至90 d[(8.95±1.83)mmol/L与(6.21±1.14)mmol/L],差异有统计学意义(t=-3.291,P＜0.05);雌性FGR鼠90 d时FPG为(9.08±1.65)mmol/L,高于对照组的(6.73土0.67)mmol/L,差异有统计学意义(t=-3.226,P＜0.05);雄性FGR鼠FINS 30 d时开始高于对照组,直至90 d时;雌性FGR鼠60及90 d时FINS 高于对照组,差异均有统计学意义(P＜0.05);雄性及雌性FGR鼠胰岛素抵抗指数及胰岛素敏感指数分别于30 d及60 d始与对照组相比出现改变,直至90 d,差异有统计学意义(P均＜0.05).腹腔葡萄糖耐量实验结果显示,从0 min始各时间点雄性和雌性FGR鼠血糖均高于对照组,差异均有统计学意义(P＜0.05).(3)生后90 d时,雄性FGR鼠糖化血红蛋白为(7.03±0.54)%,高于对照组的(4.37±0.64)%,差异有统计学意义(t=-8.028,P＜0.05).无论雄性或雌性仔鼠,2组血脂水平差异均无统计学意义(P均＞0.05).结论 FGR鼠在生后早期尚能维持正常的FPG和FINS水平,随着日龄增加,胰岛素敏感性从青年期逐渐降低,直至成年期,而且雄性FGR鼠更易发生胰岛素抵抗. 目的探討胎兒生長受限(fetal growth restriction,FGR)大鼠胰島素敏感性的變化規律.方法母鼠受孕後第1天始隨機分為對照組和低蛋白組,各10隻.低蛋白組孕鼠採用低蛋白飲食法建立FGR模型.低蛋白組仔鼠中齣生體重低于對照組仔鼠平均齣生體重兩箇標準差者定為FGR鼠.測定對照組和FGR仔鼠(每組雌雄各8隻)生後3、7、14、30、60及90 d空腹血漿血糖(fasting plasma glucose,FPG)及空腹血清胰島索(fasting serum insulin,FINS),計算胰島素牴抗指數及胰島素敏感指數.90 d時測定血甘油三酯、低密度脂蛋白膽固醇、高密度脂蛋白膽固醇和糖化血紅蛋白,同時行腹腔葡萄糖耐量實驗.結果 (1)低蛋白組仔鼠平均齣生體重為(4.92±0.36)g,低于對照組的(6.43±0.59)g,差異有統計學意義(t=14.73,P＜0.05).(2)雄性FGR鼠生後60 d時FPG高于對照組[(9.38±1.57)mmol/L與(5.58士1.24)mmol/L],直至90 d[(8.95±1.83)mmol/L與(6.21±1.14)mmol/L],差異有統計學意義(t=-3.291,P＜0.05);雌性FGR鼠90 d時FPG為(9.08±1.65)mmol/L,高于對照組的(6.73土0.67)mmol/L,差異有統計學意義(t=-3.226,P＜0.05);雄性FGR鼠FINS 30 d時開始高于對照組,直至90 d時;雌性FGR鼠60及90 d時FINS 高于對照組,差異均有統計學意義(P＜0.05);雄性及雌性FGR鼠胰島素牴抗指數及胰島素敏感指數分彆于30 d及60 d始與對照組相比齣現改變,直至90 d,差異有統計學意義(P均＜0.05).腹腔葡萄糖耐量實驗結果顯示,從0 min始各時間點雄性和雌性FGR鼠血糖均高于對照組,差異均有統計學意義(P＜0.05).(3)生後90 d時,雄性FGR鼠糖化血紅蛋白為(7.03±0.54)%,高于對照組的(4.37±0.64)%,差異有統計學意義(t=-8.028,P＜0.05).無論雄性或雌性仔鼠,2組血脂水平差異均無統計學意義(P均＞0.05).結論 FGR鼠在生後早期尚能維持正常的FPG和FINS水平,隨著日齡增加,胰島素敏感性從青年期逐漸降低,直至成年期,而且雄性FGR鼠更易髮生胰島素牴抗.
목적 탐토태인생장수한(fetal growth restriction,FGR)대서이도소민감성적변화규률.방법 모서수잉후제1천시수궤분위대조조화저단백조,각10지.저단백조잉서채용저단백음식법건립FGR모형.저단백조자서중출생체중저우대조조자서평균출생체중량개표준차자정위FGR서.측정대조조화FGR자서(매조자웅각8지)생후3、7、14、30、60급90 d공복혈장혈당(fasting plasma glucose,FPG)급공복혈청이도색(fasting serum insulin,FINS),계산이도소저항지수급이도소민감지수.90 d시측정혈감유삼지、저밀도지단백담고순、고밀도지단백담고순화당화혈홍단백,동시행복강포도당내량실험.결과 (1)저단백조자서평균출생체중위(4.92±0.36)g,저우대조조적(6.43±0.59)g,차이유통계학의의(t=14.73,P＜0.05).(2)웅성FGR서생후60 d시FPG고우대조조[(9.38±1.57)mmol/L여(5.58사1.24)mmol/L],직지90 d[(8.95±1.83)mmol/L여(6.21±1.14)mmol/L],차이유통계학의의(t=-3.291,P＜0.05);자성FGR서90 d시FPG위(9.08±1.65)mmol/L,고우대조조적(6.73토0.67)mmol/L,차이유통계학의의(t=-3.226,P＜0.05);웅성FGR서FINS 30 d시개시고우대조조,직지90 d시;자성FGR서60급90 d시FINS 고우대조조,차이균유통계학의의(P＜0.05);웅성급자성FGR서이도소저항지수급이도소민감지수분별우30 d급60 d시여대조조상비출현개변,직지90 d,차이유통계학의의(P균＜0.05).복강포도당내량실험결과현시,종0 min시각시간점웅성화자성FGR서혈당균고우대조조,차이균유통계학의의(P＜0.05).(3)생후90 d시,웅성FGR서당화혈홍단백위(7.03±0.54)%,고우대조조적(4.37±0.64)%,차이유통계학의의(t=-8.028,P＜0.05).무론웅성혹자성자서,2조혈지수평차이균무통계학의의(P균＞0.05).결론 FGR서재생후조기상능유지정상적FPG화FINS수평,수착일령증가,이도소민감성종청년기축점강저,직지성년기,이차웅성FGR서경역발생이도소저항.
Objective To investigate the regular pattern of dynamic changes of insulin sensitivity in fetal growth restriction (FGR) rats. Methods Twenty pregnant female rats were randomly divided into two groups as normal-protein group (NP) and low-protein group (LP), which respectively received normal protein diet (20% protein) and low protein diet (8% protein) during pregnancy. Weights of newborns were measured within 6 hours after birth, and the LP offspring whose birth weights were at least 2 standard deviations below the mean of NP offspring (≤2 standard deviations) were defined as FGR rats. At day 3, 7, 14, 30, 60 and 90 after birth, rats were fasted for 12 hours and then angular vein blood was collected to measure fasting plasma glucose (FPG) and fasting serum insulin (FINS) level. At 90 days of age, intraperitoneal glucose tolerance test (IPGTT)was performed; and blood triglyceride ( TG ), low-density lipoprotein cholesterol ( LDL-C ),high-density lipoprotein cholesterol (HDL-C) and glycosylated hemoglobin Alc (HbAlc) were measured. Insulin sensitivity was evaluated by FINS, insulin resistance index (HOMA-IR), insulin sensitivity index (ISI) and IPGTT. Results (1) Birth weights of LP offspring [(4. 92 ± 0. 36) g]were significantly lower than those of NP ones [(6. 43 ± 0. 59) g] (t = 14. 73, P＜0. 05). The incidence of FGR in LP was 88. 2% ; and for the male and female rats, the FGR rate was 94. 1% and 83. 1%, respectively. (2) FPG levels in the male FGR rats were significantly higher than in the NP from the age of 60 days [(9.38 ± 1.57) mmol/L vs (5. 58 ± 1.24) mmol/L] to 90 days [(8. 95 ±1.83) mmol/L vs (6. 21± 1.14) mmol/L] (t=-3. 291, P＜0. 05), while FPG levels in female FGR rats increased significantly only at 90 days of age [(9. 08±1.65) mmol/L vs (6.73±0. 67) mmol/L](t=-3. 226,P＜0. 05). FINS levels were significantly higher in FGR rats than in the NP from the age of 30 days (male FGR rats) or 60 days (female FGR rats) to 90 days (P＜0. 05, respectively).Similarly, HOMA-IR was significantly higher in FGR rats than in the NP at the age of 30 days (male FGR rats) or 60 days (female FGR rats) to 90 days (P＜0. 05, respectively). ISI in male FGR rats showed a reduction in comparison with the NP from the age of 30 to 90 days, while as to the female FGR rats it was significantly lower than in the NP only at 60 days of age and continued to 90 days (P＜0. 05, respectively). IPGTT showed that after injection of glucose, blood glucose at all four points (from 0 min to 120 min) in both male and female FGR rats were higher than that in the NP (P＜0. 05). (3) No significant difference was observed in TG, LDL-C and HDL-C at 90 days of age between the FGR rats and NP ones, while HbA1c in the male FGR rats was significantly higher than that in the NP [(7. 03±0. 54) % vs (4. 37±0. 64)%,t= -8. 028, P＜0. 05]. Conclusions FGR rats are able to maintain glucose balance and normal insulin levels during their earlier age, while insulin sensitivity decreased from adolescence to adulthood. The change of insulin sensitivity is different between male and female FGR rats, and male FGR rats are more likely to develop insulin resistance.