背景:蛋白质非酶糖基化与糖尿病并发症相关.前期实验表明荞麦花总黄酮能改善糖耐量,此作用是否与荞麦花总黄酮抑制蛋白质的非酶糖基化有关尚不清除.目的:观察养麦花总黄酮对蛋白质非酶糖基化终产物形成的影响.设计:观察对比实验.地点:华北煤炭医学院药理学教研室.材料:选用75只成年SD大鼠,清洁级,雌性大鼠38只,雄性大鼠37只,体质量(200±20)g,由北京中国医学科学院实验动物研究所提供(合格证号:SCXK11-00-0006).养麦花总黄酮自制,血糖试剂盒(北京中生北控生物科技股份有限公司),青霉素(批号031020,80万单位,购自华北制药股份有限公司),链霉素(华北制药股份有限公司,批号030920,100万单位),链脲佐菌素(Sigma公司),果糖胺试剂(南京建成生物工程研究所),牛血清白蛋白(BSA)(购自Sigma公司),其他试剂为国产分析纯.方法:实验于2004-03/2004-10在华北煤炭医学院药理学教研室完成.实验1,体外大分子糖基化终产物测定:①造模和分组:将大鼠按体质量分为3组:正常对照组15只:腹腔注射生理盐水8 mL/kg.治疗组45只:大鼠禁食16 h后,腹腔注射链脲佐菌素80mg/kg,8 mL/kg,72 h后取尾静脉血测血糖,凡空腹血糖≥15 mmol/L作为糖尿病大鼠,摸球法将治疗组大鼠分为3个亚组,每组15只,分别灌胃给予0.1,0.2,0.4 g/kg荞麦花总黄酮.模型组15只:仅将大鼠制作成糖尿病模型,腹腔注射链脲佐菌素80 mg/kg,8 mL/kg.正常对照组和模型组大鼠用等容积常用水灌胃,上述各组灌胃均为1次/d,连续12周.②空腹血糖的测定:治疗组大鼠末次给药后禁食12 h,取尾静脉血,采用葡萄糖氧化酶法测其空腹血糖,其他组别大鼠在相应时间点给予相应测量作为对照.③血浆及肾组织果糖胺及大分子糖基化终产物含量检测:各组大鼠乙醚麻醉后颈动脉取血,分离血浆,同时取肾脏,制成质量分数为100g/L肾脏组织匀浆,低温离心.按试剂盒要求测定血浆及肾匀浆上清果糖胺含量,用荧光分光光度计测定血浆及肾组织匀浆上清荧光强度,观察样品的大分子糖基化终产物生成量.实验2,体外大分子糖基化终产物测定:配置葡萄糖含量为0.2mol/L、牛血清白蛋白含量20 g/L的磷酸盐缓冲液,加入青霉素20万U/L,链霉素20万U/L得A液.用A液配制终浓度为0.01,0.05,0.10 mg/L的养麦花总黄酮混悬液各60mL,将不加药物完整的非酶糖基化系统、不加药物不含糖的系统、加药物不含白蛋白的系统和加药物不含糖的系统设为对照,每1样品作5个平行管,作为体外糖基化的培养液,将配好的蛋白糖基化培养液放入37℃的恒温箱内培养孵化,于第4,8,12周分别无菌取部分培养液,按上述方法测定大分子糖基化终产物的荧光值,并计算抑制率,观察荞麦花总黄酮对体外大分子糖基化终产物的抑制情况.主要观察指标:实验1中大鼠空腹血糖、血浆及肾组织果糖胺及大分子糖基化终产物含量检测结果;实验2中荞麦花总黄酮对体外大分子糖基化终产物的抑制情况.结果:实验1:纳入大鼠75只,56只造模成功并进入结果分折.模型组大鼠血糖值、血浆及肾脏果糖胺均明显高于正常对照组(t=7.572,10.186,5.794,P<0.01).荞麦花总黄酮3个剂量治疗组血糖值均明显低于模型组(t=3.357,4.382,3.938,P<0.05~0.01),荞麦花总黄酮0.1g/kg组血浆及肾脏果糖胺与模型组相近(P>0.05),荞麦花总黄酮0.2,0.4 g/kg组血浆及肾脏果糖胺均明显低于模型组(t=5.109,4.605,3.731,3.097,P<0.05~0.01).模型组大鼠血浆及肾脏大分子糖基化终产物生成量均明显高于正常对照组(t=6.463,12.704,P>0.05),而治疗组大鼠血浆大分子糖基化终产物含量与模型对照组相近(P<0.01).治疗组各亚组肾脏大分子糖基化终产物含量均明显低于模型组(t=9.845,12.799,12.899,P<0.01).实验2:随时间的推移,各组大分子糖基化终产物的产生均逐渐增加,而各组荞麦花总黄酮均能不同程度的抑制大分子糖基化终产物的产生,并有明显的量效关系,呈现出剂量和时间依赖性.结论:荞麦花总黄酮能明显抑制在体内外蛋白质非酶糖基化终产物的形成.
揹景:蛋白質非酶糖基化與糖尿病併髮癥相關.前期實驗錶明蕎麥花總黃酮能改善糖耐量,此作用是否與蕎麥花總黃酮抑製蛋白質的非酶糖基化有關尚不清除.目的:觀察養麥花總黃酮對蛋白質非酶糖基化終產物形成的影響.設計:觀察對比實驗.地點:華北煤炭醫學院藥理學教研室.材料:選用75隻成年SD大鼠,清潔級,雌性大鼠38隻,雄性大鼠37隻,體質量(200±20)g,由北京中國醫學科學院實驗動物研究所提供(閤格證號:SCXK11-00-0006).養麥花總黃酮自製,血糖試劑盒(北京中生北控生物科技股份有限公司),青黴素(批號031020,80萬單位,購自華北製藥股份有限公司),鏈黴素(華北製藥股份有限公司,批號030920,100萬單位),鏈脲佐菌素(Sigma公司),果糖胺試劑(南京建成生物工程研究所),牛血清白蛋白(BSA)(購自Sigma公司),其他試劑為國產分析純.方法:實驗于2004-03/2004-10在華北煤炭醫學院藥理學教研室完成.實驗1,體外大分子糖基化終產物測定:①造模和分組:將大鼠按體質量分為3組:正常對照組15隻:腹腔註射生理鹽水8 mL/kg.治療組45隻:大鼠禁食16 h後,腹腔註射鏈脲佐菌素80mg/kg,8 mL/kg,72 h後取尾靜脈血測血糖,凡空腹血糖≥15 mmol/L作為糖尿病大鼠,摸毬法將治療組大鼠分為3箇亞組,每組15隻,分彆灌胃給予0.1,0.2,0.4 g/kg蕎麥花總黃酮.模型組15隻:僅將大鼠製作成糖尿病模型,腹腔註射鏈脲佐菌素80 mg/kg,8 mL/kg.正常對照組和模型組大鼠用等容積常用水灌胃,上述各組灌胃均為1次/d,連續12週.②空腹血糖的測定:治療組大鼠末次給藥後禁食12 h,取尾靜脈血,採用葡萄糖氧化酶法測其空腹血糖,其他組彆大鼠在相應時間點給予相應測量作為對照.③血漿及腎組織果糖胺及大分子糖基化終產物含量檢測:各組大鼠乙醚痳醉後頸動脈取血,分離血漿,同時取腎髒,製成質量分數為100g/L腎髒組織勻漿,低溫離心.按試劑盒要求測定血漿及腎勻漿上清果糖胺含量,用熒光分光光度計測定血漿及腎組織勻漿上清熒光彊度,觀察樣品的大分子糖基化終產物生成量.實驗2,體外大分子糖基化終產物測定:配置葡萄糖含量為0.2mol/L、牛血清白蛋白含量20 g/L的燐痠鹽緩遲液,加入青黴素20萬U/L,鏈黴素20萬U/L得A液.用A液配製終濃度為0.01,0.05,0.10 mg/L的養麥花總黃酮混懸液各60mL,將不加藥物完整的非酶糖基化繫統、不加藥物不含糖的繫統、加藥物不含白蛋白的繫統和加藥物不含糖的繫統設為對照,每1樣品作5箇平行管,作為體外糖基化的培養液,將配好的蛋白糖基化培養液放入37℃的恆溫箱內培養孵化,于第4,8,12週分彆無菌取部分培養液,按上述方法測定大分子糖基化終產物的熒光值,併計算抑製率,觀察蕎麥花總黃酮對體外大分子糖基化終產物的抑製情況.主要觀察指標:實驗1中大鼠空腹血糖、血漿及腎組織果糖胺及大分子糖基化終產物含量檢測結果;實驗2中蕎麥花總黃酮對體外大分子糖基化終產物的抑製情況.結果:實驗1:納入大鼠75隻,56隻造模成功併進入結果分摺.模型組大鼠血糖值、血漿及腎髒果糖胺均明顯高于正常對照組(t=7.572,10.186,5.794,P<0.01).蕎麥花總黃酮3箇劑量治療組血糖值均明顯低于模型組(t=3.357,4.382,3.938,P<0.05~0.01),蕎麥花總黃酮0.1g/kg組血漿及腎髒果糖胺與模型組相近(P>0.05),蕎麥花總黃酮0.2,0.4 g/kg組血漿及腎髒果糖胺均明顯低于模型組(t=5.109,4.605,3.731,3.097,P<0.05~0.01).模型組大鼠血漿及腎髒大分子糖基化終產物生成量均明顯高于正常對照組(t=6.463,12.704,P>0.05),而治療組大鼠血漿大分子糖基化終產物含量與模型對照組相近(P<0.01).治療組各亞組腎髒大分子糖基化終產物含量均明顯低于模型組(t=9.845,12.799,12.899,P<0.01).實驗2:隨時間的推移,各組大分子糖基化終產物的產生均逐漸增加,而各組蕎麥花總黃酮均能不同程度的抑製大分子糖基化終產物的產生,併有明顯的量效關繫,呈現齣劑量和時間依賴性.結論:蕎麥花總黃酮能明顯抑製在體內外蛋白質非酶糖基化終產物的形成.
배경:단백질비매당기화여당뇨병병발증상관.전기실험표명교맥화총황동능개선당내량,차작용시부여교맥화총황동억제단백질적비매당기화유관상불청제.목적:관찰양맥화총황동대단백질비매당기화종산물형성적영향.설계:관찰대비실험.지점:화북매탄의학원약이학교연실.재료:선용75지성년SD대서,청길급,자성대서38지,웅성대서37지,체질량(200±20)g,유북경중국의학과학원실험동물연구소제공(합격증호:SCXK11-00-0006).양맥화총황동자제,혈당시제합(북경중생북공생물과기고빈유한공사),청매소(비호031020,80만단위,구자화북제약고빈유한공사),련매소(화북제약고빈유한공사,비호030920,100만단위),련뇨좌균소(Sigma공사),과당알시제(남경건성생물공정연구소),우혈청백단백(BSA)(구자Sigma공사),기타시제위국산분석순.방법:실험우2004-03/2004-10재화북매탄의학원약이학교연실완성.실험1,체외대분자당기화종산물측정:①조모화분조:장대서안체질량분위3조:정상대조조15지:복강주사생리염수8 mL/kg.치료조45지:대서금식16 h후,복강주사련뇨좌균소80mg/kg,8 mL/kg,72 h후취미정맥혈측혈당,범공복혈당≥15 mmol/L작위당뇨병대서,모구법장치료조대서분위3개아조,매조15지,분별관위급여0.1,0.2,0.4 g/kg교맥화총황동.모형조15지:부장대서제작성당뇨병모형,복강주사련뇨좌균소80 mg/kg,8 mL/kg.정상대조조화모형조대서용등용적상용수관위,상술각조관위균위1차/d,련속12주.②공복혈당적측정:치료조대서말차급약후금식12 h,취미정맥혈,채용포도당양화매법측기공복혈당,기타조별대서재상응시간점급여상응측량작위대조.③혈장급신조직과당알급대분자당기화종산물함량검측:각조대서을미마취후경동맥취혈,분리혈장,동시취신장,제성질량분수위100g/L신장조직균장,저온리심.안시제합요구측정혈장급신균장상청과당알함량,용형광분광광도계측정혈장급신조직균장상청형광강도,관찰양품적대분자당기화종산물생성량.실험2,체외대분자당기화종산물측정:배치포도당함량위0.2mol/L、우혈청백단백함량20 g/L적린산염완충액,가입청매소20만U/L,련매소20만U/L득A액.용A액배제종농도위0.01,0.05,0.10 mg/L적양맥화총황동혼현액각60mL,장불가약물완정적비매당기화계통、불가약물불함당적계통、가약물불함백단백적계통화가약물불함당적계통설위대조,매1양품작5개평행관,작위체외당기화적배양액,장배호적단백당기화배양액방입37℃적항온상내배양부화,우제4,8,12주분별무균취부분배양액,안상술방법측정대분자당기화종산물적형광치,병계산억제솔,관찰교맥화총황동대체외대분자당기화종산물적억제정황.주요관찰지표:실험1중대서공복혈당、혈장급신조직과당알급대분자당기화종산물함량검측결과;실험2중교맥화총황동대체외대분자당기화종산물적억제정황.결과:실험1:납입대서75지,56지조모성공병진입결과분절.모형조대서혈당치、혈장급신장과당알균명현고우정상대조조(t=7.572,10.186,5.794,P<0.01).교맥화총황동3개제량치료조혈당치균명현저우모형조(t=3.357,4.382,3.938,P<0.05~0.01),교맥화총황동0.1g/kg조혈장급신장과당알여모형조상근(P>0.05),교맥화총황동0.2,0.4 g/kg조혈장급신장과당알균명현저우모형조(t=5.109,4.605,3.731,3.097,P<0.05~0.01).모형조대서혈장급신장대분자당기화종산물생성량균명현고우정상대조조(t=6.463,12.704,P>0.05),이치료조대서혈장대분자당기화종산물함량여모형대조조상근(P<0.01).치료조각아조신장대분자당기화종산물함량균명현저우모형조(t=9.845,12.799,12.899,P<0.01).실험2:수시간적추이,각조대분자당기화종산물적산생균축점증가,이각조교맥화총황동균능불동정도적억제대분자당기화종산물적산생,병유명현적량효관계,정현출제량화시간의뢰성.결론:교맥화총황동능명현억제재체내외단백질비매당기화종산물적형성.
BACKGROUND: Non-enzymatic glycation of proteins is involved in the complications of diabetes mellitus. Previous experiments have demonstrated that total flavones of buckwheat flower (TFBF) could improve carbohydrate tolerance. However, it is little known whether TFBF inhibit the non-enzymatic glycation of proteins.OBJECTIVE: To investigate the influences of TFBF on the non-enzymatic advanced glycation end products (AGEs) of proteins in vivo and in vitro.DESIGN: Completely randomized controlled trial.SETTING: Department of Pharmacology, North China Coal Medical College.MATERIALS: Totally 75 adult SD rats , of clean grade, weighing (200±20) g, including 38 female rats and 37 male rats, were provided by the institute of experimental animals, Chinese Academy of Medical Sciences (Certification No. SCXK11-00-0006). TFBF was extracted by our laboratory from flowers of buckwheat. The blood glucose kit was purchased from Beijing Biosino Biotechnology Company Ltd. Penicillin (Batch No.031020, 8×105 U) and streptomycin (Batch No. 030920, 1×106 U) were purchased from North China Pharmaceutical Company. Streptozotocin and BSA were purchased from Sigma Company. Fructosamine kit was purchased from Nanjing Jiancheng Bioengineering Institute, and the other chemicals were analytical pure produced domestically.METHODS: This experiment was carried out in the Department of Pharmacology, North China Coal Medical College from March to October 2004.In the first experiment, in vivo macromolecular AGEs was measured: ①Modeling and grouping: Rats were divided into 3 groups according to body mass: Normal control group (n=15), the rats were treated with 8 mL/kg normal saline intraperitoneally. Streptozotocin-treated group (n=45), the rats were fasted for 16 hours and then treated with 80 mg/kg streptozotocin of 8 mL/kg intraperitoneally. Twenty-two hours later, the blood of all rats was harvested from vena caudalis to measure the level of blood sugar.Those with fasting blood glucose ≥ 15 mmol/L were acted as diabetic rats.Streptozotocin-treated group were divided into 3 subgroups, 15 rats in each subgroups. Each rat was given intragastric administration of 0.1, 0.2 and 0.4 g/kg TFBF. Model group (n=1S): Rats were only treated with 80 mg/kg streptozotocin of 8 mL/kg . The rats in normal control group and model group were given the same volume of salt water. The administration was once a day for 12 weeks successively. ②Measurement of fasting blood glucose: After the last administration, the rats of streptozotocin-treated group were fasted for 12 hours and the blood was harvested from vena caudalis. The fasting blood glucose was measured by glucose oxidase method. ③The levels of blood plasma and nephridial tissue fructosamine and macromolecular AGEs were measured: The rats of each group were anesthetized with ethyl ether on the second day following the last administration. Blood was chosen from carotid artery, and plasma was separated.Kidneys were taken at the same time, prepared into 100 g/L tissue homogenate and centrifuged at low temperature. The levels of fructosamine in plasma and the supernatant fluid of kidney homogenate were measured according to the instructions of the kit. AGEs in plasma and renal tissue were determined by fluorospectrophotometer. The products of macromolecular AGEs were calculated. In the second experiment, in vitro macromolecular AGEs were measured as below: 0.01, 0.05, 0.10 mg/L TFBF of 6 mLrespectively was prepared with solution A (0.2 mol/L glucose, 2×l06 U/Lpenicillin, 2×106 U/L streptomycin , PBS containing 20 g/L bovine serum albumin). Control groups were set: ① without TFBF, ② without TFBF and glucose, ③ without BSA, ④ without glucose. Five parallels of each sample were sterilized by filtration and incubated in the attemperator at 37 ℃. The fluorescence of AGEs (F) in the culture was determined at the 4th, 8th and 12th weeks. Inhibition ratio (IR) was calculated and the inhibition of TFBF on AGEs was observed.MAIN OUTCOME MEASURES: In the first experiment, the levels of fasting blood glucose, fructosamine in kidney and plasma, and AGEs were measured. In the second experiment, the inhibition of TFBF on AGEs in vitro was measured.RESULTS: In the first experiment, 75 rats were involved, and 56 successful rats entered the stage of result analysis. The levels of blood glucose,fructosamine in kidney and plasma of rats in the model group were significantly higher than those of rats in the normal control group (t=7.572,10.186, 5.794,P < 0.01 ). The level of blood glucose of rats in the 3 subgroups was significantly lower than that of rats in the model group (t=3.357,4.382,3.938,P < 0.05-0.01); The levels of fructosamine in kidney and plasma of rats in the 0.2 and 0.4 g/kg TFBF groups were significantly lower than those in the model group (t=5.109, 4.605, 3.731,3.097,P < 0.05-0.01 ). The levels of AGEs in plasma and kidney of rats in the model group were significantly higher than those in the normal control group (t=6.463, 12.704,P < 0.01 ), while the levels of AGEs in plasma of rats in the streptozotocin-treated group were similar to those in the model control group (P >. 0.05), and those in kidney of rats in the streptozotocintreated subgroups were significantly lower than those in the model group (t=9.845, 12.799, 12.899,P < 0.01 ). In the second experiment, the level of macromolecular AGEs of each group was gradually increased with ime.TFBFcould inhibit the formation of macromolecular AGEs in dose- and time-dependent manner.CONCLUSION: TFBF obviously inhibited the formation of AGEs of proteins in vivo and in vitro.