Study the Dynamic Thiol -Disulfide Homeostasis in patients with Diabetes type I and type 2

Main Article Content

Zainab M.Qassam
Ekhlass M. Taha

Keywords

Dynamic Thiol, Native thiol, Diabetes , protein

Abstract

Background: Diabetes is a condition in which the levels of blood glucose are abnormally high (also known as blood sugar). Diabetes mellitus is a rapidly expanding global problem with significant social, health, and economic implications.
Methodology: 144 volunteers were enrolled in the current study, The volunteers were divided into four groups: the first group consist of 21 subjects with control type 1, the second group consist of 51 patients with type 1, the third group consist of 20 subjects with control type 2, and the fourth group consists of 55 subjects with patients type 2. Total thiol, Native thiol, F.B.S, and Total protein concentrations were determined using an absorbance spectrophotometer.Hba1c concentration was determined using an i-chroma.
Results: The result of Total thiol, Native thiol ,Dynamic thiol-disulfide, and Total protein thiol showed a non -significant change between the fourth groups. The level of serum Hba1c and F.B.S showed a significant change among fourth groups.
Conclusion: Total thiol, Native thiol, Dynamic thiol-disulfide, and Total protein do not effect by Diabetes type 1and type 2.

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References

1. Glovaci D, Fan W, Wong ND. Epidemiology of diabetes mellitus and cardiovascular disease. Current cardiology reports. 2019 Apr;21(4):1-8.
2. Rajput R, Sinha B, Majumdar S, Shunmugavelu M, Bajaj S. Consensus statement on insulin therapy in chronic kidney disease. Diabetes research and clinical practice. 2017 May 1;127:10-20.
3. Nelson DL, Lehninger AL, Cox MM. Lehninger principles of biochemistry. Macmillan; 2008.
4. Zhao X, Hirota T, Han X, Cho H, Chong LW, Lamia K, et al. Circadian amplitude regulation via FBXW7-targeted REV-ERBα degradation. Cell. 2016Jun;165:1644–57.
5. Kourtis N, Moubarak RS, Aranda-Orgilles B, Lui K, Aydin IT, Trimarchi T, et al. FBXW7 modulates cellular stress response and metastatic
potential through HSF1 post-translational modification. Nat Cell Biol. 2015;17:322–32.
6. Lee WC, Mokhtar SS, Munisamy S, Yahaya S, Rasool AH. Vitamin D status and oxidative stress in diabetes mellitus. Cellular and Molecular Biology. 2018 May 30;64(7):60-9.
7. Kükürt A, Gelen V, Başer ÖF, Deveci HA, Karapehlivan M. Thiols: Role in oxidative stress-related disorders. InLipid Peroxidation 2021 Mar 20. IntechOpen
8. Wang Z, Yu C, Wang J, Bao J, Gao X, Xiang H. Age-period-cohort analysis of suicide mortality by gender among white and black Americans, 1983–2012. International journal for equity in health. 2016 Dec;15(1):1-9.
9. Wang S, Ding L, Ji H, Xu Z, Liu Q, Zheng Y. The role of p38 MAPK in the development of diabetic cardiomyopathy. International journal of molecular sciences. 2016 Jul;17(7):1037.
10. Mordarska K, Godziejewska-Zawada M. Diabetes in the elderly. Przeglad menopauzalny= Menopause review. 2017 Jun;16(2):38.
11. Al-Attaby AK, Al-Lami MQ. Effect of age and gender on some biochemical, hormones and adipocytokines parameters in Iraq type 2 diabetes mellitus patients. Int. Res. J. Pharm.2018;9(12).
12. Haglund, A.C.; Ek, B.; Ek, P. Phosphorylation of human plasma _2-Heremans-Schmid glycoprotein (human fetuin) in vivo. Biochem. J. 2001, 357, 437–445.
13. Lima VC, Cavalieri GC, Lima MC, Nazario NO, Lima GC. Risk factors for diabetic retinopathy: a case–control study. International journal of retina and vitreous. 2016 Dec;2(1):1-7.

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