Shibayagi 小鼠胰岛素 ELISA试剂盒(T型)

Shibayagi 小鼠胰岛素 ELISA试剂盒(T型)
Lbis® Insulin-Mouse-T

  • 产品特性
  • 相关资料
  • Q&A
  • 参考文献

Lbis® Insulin-Mouse-TShibayagi 小鼠胰岛素 ELISA试剂盒(T型)

Shibayagi 小鼠胰岛素 ELISA试剂盒(T型)

Shibayagi 小鼠胰岛素 ELISA试剂盒(T型)

  胰岛素是由胰脏内的胰岛β细胞分泌,分子量约5800,等电点在5.4左右的一种蛋白质激素。

  A6-A11、A7-B7、A20-B-19之间形成二硫键,在酸性溶液或者不含Zn离子的中性水溶液中形成二聚体,在含锌离子的中性溶液中,则形成含2个Zn离子的六聚体。

  肝脏、肌肉、脂肪组织是主要的靶组织,分别有以下的作用。

肝脏:促进糖原、蛋白质、脂肪酸合成、促进糖类的摄取和利用、抑制糖异生。

肌肉:糖类、氨基酸、K细胞膜通透性增大、促进糖原、蛋白质的合成、抑制蛋白质分解。

脂肪组织:葡萄糖细胞膜通透性增大、促进脂肪酸的合成。

  胰岛素是细胞内的合成单链胰岛素原通过二硫键结合一起形成的。在酶分解作用下被激活,C肽和胰岛素分离。

◆特点

● 短时间测定(总的反应时间:3小时)

● 微量样品(标准操作:10 μL)可测

● 使用对环境无害的防腐剂

● 全部试剂均为液体,可直接使用

● 精密的测定精度和高再现性

● 操作简便,不需要特别的预处理

● 有效期限为12个月

◆构成

组成部分

状态

容量

(A) 抗体固相化 96孔板

洗净后使用

96 wells(8×12)/1 块

(B) 胰岛素标准溶液(小鼠)(200 ng/mL)

稀释后使用

25 μL/1 瓶

(C) 缓冲液

即用

60 mL/1 瓶

(D) 生物素结合抗胰岛素抗体

稀释后使用

10 μL/1 瓶

(E) 过氧化物・抗生物素蛋白结合物

稀释后使用

20 μL/1 瓶

(F) 显色液(TMB)

即用

12 mL/1 瓶

(H) 反应终止液(1M   H2SO4)※小心轻放

即用

12 mL/1 瓶

( I ) 浓缩洗净液(10×)

稀释后使用

100 mL/1 瓶

封板膜

3 张

使用说明书

1 份

◆样品信息

小鼠的血清、血浆、培养液

10 μL/well(标准操作)

※血浆采血建议使用肝素处理血液

 

◆测量范围

0.156~10 ng/mL(标准曲线范围)

◆Validation data

精度测试(检测内变动系数)

样品

A

B

C

D

mean

0.882

1.15

3.67

5.25

SD

0.0245

0.0213

0.0649

0.0792

CV(%)

2.78

1.87

1.77

1.51

单位:ng/mL n=10

 

再现性测试(检测内变动系数)

测量日/样品

E

F

G

第0天

5.253

1.224

0.513

第1天

5.322

1.312

0.523

第2天

5.365

1.269

0.512

第3天

5.362

1.281

0.535

mean

5.326

1.272

0.521

SD

0.0520

0.0366

0.0109

CV(%)

3.31

3.76

4.65

单位:ng/mL n=3

 

添加回收测试

 

样品H

添加量

实测值

回收量

回收率(%)

0

1.350

0.25

1.593

0.243

97.2

0.50

1.841

0.491

98.2

0.75

2.065

0.715

95.3

1.00

2.299

0.949

94.9

单位:ng/mL n=3

 

样品I

添加量

实测值

回收量

回收率(%)

0

1.941

0.50

2.496

0.505

101

0.75

2.728

0.737

98.3

1.00

2.955

0.964

96.4

1.50

3.431

1.440

96.0

单位:ng/mL n=3

 

稀释直线性测试

 

用稀释缓冲液分3次连续稀释3个血清样品的测量结果,直线回归方程的R2在0.993~0.999之间。

相关资料


Shibayagi 小鼠胰岛素 ELISA试剂盒(T型) Shibayagi 小鼠胰岛素 ELISA试剂盒(T型) Shibayagi 小鼠胰岛素 ELISA试剂盒(T型)
说明书

ELISA试剂盒选择指南①②

ELISA试剂盒选择指③④

参考文献



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Alteration of gut microbiota by vancomycin and bacitracin improves insulin resistance via glucagon-like peptide 1 in diet-induced obesity. Hwang I, Park YJ, Kim YR, Kim YN, Ka S, Lee HY, Seong JK, Seok YJ, Kim JB. FASEB J. Vol.29(6), p2397-411, Jun 2015.


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59.

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63.

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64.

Optogenetic control of insulin secretion by pancreatic β-cells in vitro and in vivo. Kushibiki T, Okawa S, Hirasawa T, Ishihara M. Gene Ther. Mar 2015.


65.

Compensatory hyperinsulinemia in high-fat diet-induced obese mice is associated with enhanced insulin translation in islets. Kanno A, Asahara S, Masuda K, Matsuda T, Kimura-Koyanagi M, Seino S, Ogawa W, Kido Y. Biochem Biophys Res Commun. Vol.458(3), p681-6, Mar 2015.


66.

Essential role of mitochondrial Ca2+ uniporter in the generation of mitochondrial pH gradient and metabolism-secretion coupling in insulin-releasing cells. Quan X, Nguyen TT, Choi SK, Xu S, Das R, Cha SK, Kim N, Han J, Wiederkehr A, Wollheim CB, Park KS. J Biol Chem. Vol.290(7), p4086-96, Feb 2015.


67.

Endogenous Interleukin 18 Suppresses Hyperglycemia and Hyperinsulinemia during the Acute Phase of Endotoxemia in Mice. Yamashita H, Aoyama-Ishikawa M, Takahara M, Yamauchi C, Inoue T, Miyoshi M, Maeshige N, Usami M, Nakao A, Kotani J. Surg Infect (Larchmt). 2015 Feb;16(1):90-6.


68.

 Hot water extracts of edible Chrysanthemum morifolium Ramat. exert antidiabetic effects in obese diabetic KK-Ay mice. Junpei Yamamoto, Miki Tadaishi, Takumi Yamane, Yuichi Oishi, Makoto Shimizu & Kazuo Kobayashi-Hattoria. Bioscience, Biotechnology, and Biochemistry, Published online: 10 Feb 2015


69.

Alteration of gut microbiota by vancomycin and bacitracin improves insulin resistance via glucagon-like peptide 1 in diet-induced obesity. Hwang I, Park YJ, Kim YR1, Kim YN, Ka S, Lee HY, Seong JK, Seok YJ, Kim JB. FASEB J. Feb 2015.


70.

Titanium dioxide nanoparticles increase plasma glucose via reactive oxygen species-induced insulin resistance in mice. Hu H, Guo Q, Wang C, Ma X, He H, Oh Y, Feng Y, Wu Q, Gu N. J Appl Toxicol. Mar 2015.


71.

Ashitaba (Angelica keiskei) extract prevents adiposity in high-fat diet-fed C57BL/6 mice. Zhang T, Yamashita Y, Yasuda M, Yamamoto N, Ashida H. Food Funct. Vol.6(1), p134-144, Jan 2015.


72.

Dietary nitrite supplementation improves insulin resistance in type 2 diabetic KKAy mice Ohtake K, Nakano G, Ehara N, Sonoda K, Ito J, Uchida H, Kobayashi J. Nitric Oxide, Vol.44, p31–38, Jan 2015.


73.

Salicornia herbacea prevents weight gain and hepatic lipid accumulation in obese ICR mice fed a high-fat diet. Pichiah PT, Cha YS. J Sci Food Agric. Dec 2014.


74.

Salacia reticulata has therapeutic effects on obesity. Shimada T, Nakayama Y, Harasawa Y, Matsui H, Kobayashi H, Sai Y, Miyamoto K, Tomatsu S, Aburada M. J Nat Med. Vol.68(4), p668-676, Oct 2014.Salicornia herbacea prevents weight gain and hepatic lipid accumulation in obese ICR mice fed a high-fat diet. Pichiah PT1, Cha YS. J Sci Food Agric. Dec 2014.


75.

Ghrelin administered spinally increases the blood glucose level in mice. Sim Y-B., Park S-H., Kim S-S., Kim C-H., Kim S-J., Lim S-M., Jung J-S., Suh H-W. Peptides, Vol.54, p162-165, Apr 2014.

76.

Chronic exposure to valproic acid promotes insulin release, reduces KATP channel current and does not affect Ca2+ signaling in mouse islets. Manaka K., Nakata M., Shimomura K., Rita RS., Maejima Y., Yoshida M., Dezaki K., Kakei M., Yada T. The Journal of Physiological Sciences, Vol.64(1), p77-83, Jan 2014.


77.

Impaired Lipid and Glucose Homeostasis in Hexabromocyclododecane-Exposed Mice Fed a High-Fat Diet. Yanagisawa R., Koike E., Win-Shwe TT., Yamamoto M. and Takano H. ENVIRONMENTAL HEALTH PERSPECTIVES, Jan 2014.


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Lipid-Lowering Effects of Pediococcus acidilactici M76 Isolated from Korean Traditional Makgeolli in High Fat Diet-Induced Obese Mice. Moon Y-J., Baik S-H. and Cha Y-S. Nutrients, Vol.6(3), p1016-1028, 2014.


79.

Azilsartan, an angiotensin II type 1 receptor blocker, restores endothelial function by reducing vascular inflammation and by increasing the phosphorylation ratio Ser1177/Thr497 of endothelial nitric oxide synthase in diabetic mice. Matsumoto S., Shimabukuro M., Fukuda D., Soeki T., Yamakawa K., Masuzaki H. and Sata M. Cardiovascular Diabetology, 13:30, 2014.


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Intake of mulberry 1-deoxynojirimycin prevents diet-induced obesity through increases in adiponectin in mice. T.Tsuduki, I.Kikuchi, T.Kimura, K.Nakagawa, T.Miyazawa. Food Chemistry, Vol.139(1-4), p16-23, Aug 2013.


81.

Chronic treatment with novel GPR40 agonists improve whole-body glucose metabolism based on the glucose-dependent insulin secretion. H.Tanaka, S.Yoshida, H.Oshima, H.Minoura, K.Negoro, T.Yamazaki, S.Sakuda, F.Iwasaki, T.Matsui and M. Shibasaki. JPET, Jul 2013.


82.

Contribution of insulin signaling to the regulation of pancreatic beta-cell mass during the catch-up growth period in a low birth weight mouse model. Y.Yoshida, M.Fuchita, M.Kimura-Koyanagi, A.Kanno, T.Matsuda, S.Asahara, N.Hashimoto, T.Isagawa, W.Ogawa, H.Aburatani, T.Noda, S.Seino, M.Kasuga, Y.Kido. Diabetology International, Jul 2013.


83.

Differential contribution of insulin and amino acids to the mTORC1-autophagy pathway in the liver and muscle. T.Naito, A.Kuma and N.Mizushima. The Journal of Biological Chemistry, Jun 2013.


84.

Apelin Inhibits Diet-Induced Obesity by Enhancing Lymphatic and Blood Vessel Integrity. M.Sawane, K.Kajiya, H.Kidoya, M.Takagi, F.Muramatsu and N.Takakura. Diabetes, Vol.62(6), p1970-1980, Jun 2013.


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Ras-related C3 botulinum toxin substrate 1 (RAC1) regulates glucose-stimulated insulin secretion via modulation of F-actin. S.Asahara, Y.Shibutani, K.Teruyama, H.Y.Inoue, Y.Kawada, H.Etoh, T.Matsuda, M.Kimura-Koyanagi, N.Hashimoto, M.Sakahara, W.Fujimoto, H.Takahashi, S.Ueda, T.Hosooka, T.Satoh, H.Inoue, M.Matsumoto, A.Aiba, M.Kasuga, Y.Kido. Diabetologia, Vol.56(5), p1088-1097, May 2013.


86.

Effects of hydrophilic statins on renal tubular lipid accumulation in diet-induced obese mice. K.Gotoh, T.Masaki, S.Chiba, H.Ando, K.Fujiwara, T.Shimasaki, Y.Tawara, I.Toyooka, K.Shiraishi, K.Mitsutomi, M.Anai, E.Itateyama, J.Hiraoka, K.Aoki, N.Fukunaga, T.Nawata, T.Kakuma. Obesity Research & Clinical Practice, May 2013.


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Amyloid-β Induces Hepatic Insulin Resistance In Vivo via JAK2. Y.Zhang, B.Zhou, B.Deng, F.Zhang, J.Wu, Y.Wang, Y.Le and Q.Zhai. Diabetes, Vol.62(4), p1159-1166, Apr 2013.


88.

Histidine augments the suppression of hepatic glucose production by central insulin action

Kimura K, Nakamura Y, Inaba Y, Matsumoto M, Kido Y, Asahara S, Matsuda T, Watanabe H, Maeda A, Inagaki F, Mukai C, Takeda K, Akira S, Ota T, Nakabayashi H, Kaneko S, Kasuga M and Inoue H.

Diabetes, Vol.62(4), p1003-1004, Apr 2013


89.

Improved transplantation outcome through delivery of DNA encoding secretion signal peptide-linked glucagon-like peptide-1 into mouse islets

Chae H Y, Lee M, Hwang H J, Kim H A, Kang J G, Kim C S, Lee S J, Ihm S-H.

Transplant International, Vol.26(4), p443-452, Apr 2013.


90.

Histidine augments the suppression of hepatic glucose production by central insulin action

K.Kimura, Y.Nakamura, Y.Inaba, M.Matsumoto, Y.Kido, S.Asahara, T.Matsuda, H.Watanabe, A.Maeda, F.Inagaki, C.Mukai, K.Takeda, S.Akira, T.Ota, H.Nakabayashi, S.Kaneko, M.Kasuga and H.Inoue. Diabetes, Mar 2013.


91.

Wogonin ameliorates hyperglycemia and dyslipidemia via PPARα activation in db/db mice without adverse side effects. Bak E-J, Kim J-H, Lee D-E, Choi Y-H, Kim J M, Woo G-H, Cha J-H, Yoo Y-J. Clinical Nutrition, Available online 26, Mar 2013.


92.

Extracellular Signal-Regulated Kinase in the Ventromedial Hypothalamus Mediates Leptin-Induced Glucose Uptake in Red-Type Skeletal Muscle. Toda C, Shiuchi T, Kageyama H, Okamoto S, Coutinho E A, Sato T, Okamatsu-Ogura Y, Yokota S, Takagi K, Tang L, Saito K, Shioda S and Minokoshi Y. Diabetes Mar 2013.


93.

Effect of vitamin E on alloxan-induced mouse diabetes. Kamimura W, Doi W, Takemoto K, Ishihara K, Wang D-H, Sugiyama H, Oda S, Masuoka N. Clinical Biochemistry, Mar 2013.


94.

Ablation of Rnf213 retards progression of diabetes in the Akita mouse. Kobayashi H, Yamazaki S, Takashima S, Liu W, Okuda H, Yan J, Fujii Y, Hitomi T, Harada K H, Habu T, Koizumi A. Biochemical and Biophysical Research Communications, Vol.432(3), p519-525, Mar 2013.

 

95.

Hypothalamic ATF3 is involved in regulating glucose and energy metabolism in mice. Lee Y-S, Sasaki T, Kobayashi M, Kikuchi O, Kim H-J, Yokota-Hashimoto H, Shimpuku M, Susanti V-Y, Ido-Kitamura Y, Kimura K, Inoue H, Tanaka-Okamoto M, Ishizaki H, Miyoshi J, Ohya S, Tanaka Y, Kitajima S, Kitamura T. Diabetologia, Mar 2013.


96.

Ras-related C3 botulinum toxin substrate 1 (RAC1) regulates glucose-stimulated insulin secretion via modulation of F-actin. S. Asahara, Y. Shibutani, K. Teruyama, H. Y. Inoue, Y. Kawada, H. Etoh, T. Matsuda, M. Kimura-Koyanagi, N. Hashimoto, M. Sakahara, W. Fujimoto, H. Takahashi, S. Ueda, T. Hosooka, T. Satoh, H. Inoue, M. Matsumoto, A. Aiba, M. Kasuga, Y. Kido. Diabetologia, Feb 2013.


97.

Toll-like receptor 2 and palmitic acid cooperatively contribute to the development of nonalcoholic steatohepatitis through inflammasome activation in mice. Miura K, Yang L, Rooijen N, Brenner D A, Ohnishi H, Seki E. Hepatology, Vol.57(2), p577-589, Feb 2013.


98.

Transcriptional Regulatory Factor X6 (Rfx6) Increases Gastric Inhibitory Polypeptide (GIP) Expression in Enteroendocrine K-cells and Is Involved in GIP Hypersecretion in High Fat Diet-induced Obesity*. K.Suzuki, N.Harada, S.Yamane, Y.Nakamura, K.Sasaki, D.Nasteska, E.Joo, K.Shibue, T.Harada, A.Hamasaki, K.Toyoda, K.Nagashima and N.Inagaki. The Journal of Biological Chemistry, Vol.288, p1929-1938, Jan 2013.


99.

Improved hypothermic short-term storage of isolated mouse islets by adding serum to preservation solutions. Yasuko Kimura, Teru Okitsu, Liu Xibao, Hiroki Teramae, Atsuhito Okonogi, Kentaro Toyoda, Shinji Uemoto and Masanori Fukushima. Islets, Vol.5(1), Jan 2013.


100.

Anti-diabetic effect of amorphastilbol through PPARα/γ dual activation in db/db mice. Lee W, Ham J, Kwon H C, Kim Y K, Kim S-N. Biochemical and Biophysical Research Communications, Jan 2013.

101.

Transcriptional Regulatory Factor X6 (Rfx6) Increases Gastric Inhibitory Polypeptide (GIP) Expression in Enteroendocrine K-cells and Is Involved in GIP Hypersecretion in High Fat Diet-induced Obesity. Suzuki K, Harada N, Yamane S, Nakamura Y, Sasaki K, Nasteska D, Joo E, Shibue K, Harada T, Hamasaki A,Toyoda K, Nagashima K and Inagaki N. The Journal of Biological Chemistry, Vol.288, p1929-1938, Jan 2013.


102.

Apelin inhibits diet-induced obesity by enhancing lymphatic and blood vessel integrity. Sawane M, Kajiya K, Kidoya H, Takagi M, Muramatsu F and Takakura N. Diabetes, 2013.


103.

Beneficial effects of Allium sativum L. stem extract on lipid metabolism and antioxidant status in obese mice fed a high fat diet. Kim I, Kim H-R, Kim J-H, Om A-S. Journal of the Science of Food and Agriculture, 2013.


104.

Intake of mulberry 1-deoxynojirimycin prevents diet-induced obesity through increases in adiponectin in mice. Tsuduki T, Kikuchi I, Kimura T, Nakagawa K, Miyazawa T. Food Chemistry, Vol.139(14), p16-23, 2013.


105.

Effect of Mukitake mushroom (Panellus serotinus) on the pathogenesis of lipid abnormalities in obese, diabetic ob/ob mice. Inoue N, Inafuku M, Shirouchi B, Nagao K and Yanagita T. Lipids in Health and Disease, Vol.12(18), 2013.


106.

Pax6 Directly Down-Regulates Pcsk1n Expression Thereby Regulating PC1/3 Dependent Proinsulin Processing. Liu T., Zhao Y., Tang N., Feng R., Yang X., Lu N., Wen J., Li L. PLOS ONE, Vol.7(10), Oct 2012.


107.

Anti-Diabetic Atherosclerosis Effect of Prunella vulgaris in db/db Mice with Type 2 Diabetes. Hwang S M, Kim J K, Lee Y J, Yoon J J, Lee S M, Kang D G, Lee H S. Am J Chin Med, Vol.40, 2012.


108.

Prevention mechanisms of glucose intolerance and obesity by cacao liquor procyanidin extract in high-fat diet-fed C57BL/6 mice. Y. Yamashita., M. Okabe., M. Natsume., H. Ashida. Archives of Biochemistry and Biophysics, Available online 23 March 2012, In Press


109.

The Action of D-Dopachrome Tautomerase as an Adipokine in Adipocyte Lipid Metabolism. T. Iwata., H. Taniguchi., M. Kuwajima., T. Taniguchi., Y. Okuda., A. Sukeno., K. Ishimoto., N. Mizusawa., K. Yoshimoto. PLos ONE, Vol. 7(3), Mar 2012.


110.

Soymorphin-5, a soy-derived μ-opioid peptide, decreases glucose and triglyceride levels through activating adiponectin and PPARα systems in diabetic KKAy mice. Y. Yamada.,.A. Muraki.,.M. Oie.,.N. Kanegawa.,.A. Oda., Y. Sawashi., K. Kaneko., M. Yoshikawa., T. Goto., N. Takahashi., T. Kawada., and K. Ohinata. American Physiological Society, Vol.302, No.4, E433-E440, 2012.


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Effects of Gametophytes of Ecklonia Kurome on the Levels of Glucose and Triacylglycerol in db/db, Prediabetic C57BL/6J and IFN-γ KO Mice. F. Dwiranti., M. Hiraoka., T. Taguchi., Y. Konishi., M. Tominaga., A. Tominaga. Int J B 64 iomed Sci, Vol.8, No.1, Mar 2012.


112.

Endoplasmic Reticulum Stress Inhibits STAT3-Dependent Suppression of Hepatic Gluconeogenesis via Dephosphprylation and Deacetylation. K. Kimura., T. Yamada., M. Matsumoto., Y. Kido., T. Hosooka., S. Asahara., T. Matsuda., T. Ota., H. Watanabe., Y. Sai., K. Miyamoto., S. Kaneko., M. Kasuga., H. Inoue. Diabetes, Vol.61, No.1, p61-73, 2012.


113.

Melatonin protects mice with intermittent hypoxia from oxidative stress-induced pancreatic injury. LI G., HOU G., LU W., KANG J. Sleep and Biological Rhythms, Vol.9(2), p78-85, Apr 2011.


114.

A novel dipeptidyl peptidase IV inhibitor DA-1229 ameliorates streptozotocin-induced diabetes by increasing β-cell replication and neogenesis. J, M, Cho., H, W, Jang., H, Cheon.,Y, T, Jeong., D-H, Kim., Y-M, Lim., S, Choi., E, Yang., C-Y, Shin., M, H, Son., S, H, Kim., H, Kim., M, Lee. Diabetes Research and Clinical Practice.Vol. 91(1), p72-79, 2011.


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634-01481 (AKRIN-011T)Lbis® Insulin-Mouse-T 96 tests