Published May 31, 2024 | Version https://impactfactor.org/PDF/IJPCR/16/IJPCR,Vol16,Issue5,Article473.pdf
Journal article Open

Study of Nerve Conduction in Non-Diabetic Offspring of Type 2 Diabetic Parents of Students in NMCH, Patna

Authors/Creators

  • 1. Tutor, Department of Physiology, Nalanda Medical College & Hospital, Patna, Bihar, India
  • 2. Associate Professor & HOD, Department Of Physiology, Nalanda Medical College & Hospital, Patna, Bihar, India

Description

Introduction: Diabetes is a major contributor to global morbidity and mortality. Genetic factors play a significant role in the development of the disease, and various gene polymorphisms and mutations may influence its clinical presentation. Recent studies on the genetic components of type 2 diabetes mellitus (T2DM) have demonstrated that early indications of altered brain and autonomic systems are present in even non-diabetic children of diabetic parents. Objectives: The objective is to examine the median motor nerve conduction parameters in non-diabetic offspring of parents with T2DM compared to those with non-diabetic parents, and to analyze any differences between these groups. Methods: On the hands of sixty healthy individuals between the ages of eighteen and twenty-five, a nerve conduction investigation of the motor component of the median nerve was carried out. All of the study’s participants had normal BMIs and were divided equally into two groups: 30 children of parents with T2DM  and 30 children of parents without the disease. Results: The motor component of the median nerve’s latency, amplitude, and conduction velocity did not significantly change between the two groups. Conclusion: There were no discernible variations in motor nerve latencies between the groups according to the study. This is in contrast to results from earlier research in comparable populations that showed altered visually evoked potentials and autonomic dysfunction. The lack of engagement of the somatic nerve may be explained by the glycation of neural structures, which may have an impact on neuronal activity.

 

 

 

Abstract (English)

Introduction: Diabetes is a major contributor to global morbidity and mortality. Genetic factors play a significant role in the development of the disease, and various gene polymorphisms and mutations may influence its clinical presentation. Recent studies on the genetic components of type 2 diabetes mellitus (T2DM) have demonstrated that early indications of altered brain and autonomic systems are present in even non-diabetic children of diabetic parents. Objectives: The objective is to examine the median motor nerve conduction parameters in non-diabetic offspring of parents with T2DM compared to those with non-diabetic parents, and to analyze any differences between these groups. Methods: On the hands of sixty healthy individuals between the ages of eighteen and twenty-five, a nerve conduction investigation of the motor component of the median nerve was carried out. All of the study’s participants had normal BMIs and were divided equally into two groups: 30 children of parents with T2DM  and 30 children of parents without the disease. Results: The motor component of the median nerve’s latency, amplitude, and conduction velocity did not significantly change between the two groups. Conclusion: There were no discernible variations in motor nerve latencies between the groups according to the study. This is in contrast to results from earlier research in comparable populations that showed altered visually evoked potentials and autonomic dysfunction. The lack of engagement of the somatic nerve may be explained by the glycation of neural structures, which may have an impact on neuronal activity.

 

 

 

Files

IJPCR,Vol16,Issue5,Article473.pdf

Files (295.1 kB)

Name Size Download all
md5:98033118449513d9f949f97c5609cc23
295.1 kB Preview Download

Additional details

Identifiers

URL
https://impactfactor.org/PDF/IJPCR/16/IJPCR,Vol16,Issue5,Article473.pdf

Dates

Accepted
2024-05-10

Software

Repository URL
https://impactfactor.org/PDF/IJPCR/16/IJPCR,Vol16,Issue5,Article473.pdf
Development Status
Active

References

  • 1. Wy So, Mcy Ng, Sc Lee, T. Sanke, H. K. Lee, J.C.N Chan. Genetics of type 2 diabetes mellitus. HKMKJ. 2000. 6:69-76. 2. World Health Organization. Diabetes, Factsheet Internet Geneva: World Health Organization. 2017. November. Available from http://www.who.int/ mediacentre/factsheets/fs312/en/. 3. Klein BE, Klein R, Moss SE, Cruickshanks KJ. Parental history of diabetes in a population based study. Diabetes Care. 1996; 19 (8): 827- 30. 4. Marianne AB van der Sande, Gijs EL Walraven, Paul JM Milligan, Winston AS Banya, Sana M Ceesay, Ousman A Nyan, Keith PWJ McAdam. Family history: an opportunity for early interventions and improved control of hypertension, obesity and diabetes. Bulletin of the World Health Organization, 2001.79(4): 321-8. 5. Anitha Achuthan, Janani Ramesh. Pattern Visual Evoked Potential in Non-Diabetic offsprings of Type II Diabetes. JMR 20 15;1(3):83-86. 6. Khatri Anshu, Aggarwal Tanu, Changotra Parshant. Heart Rate Variability In Non Diabetic Offsprings Of Type 2 Diabetic Patients. Journal of Advance Researches in Biological Sciences, 2013, Vol. 5 (2). P. 139- 43. 7. Goldfine AB, Beckman JA, Betensky RA, Devlin H, Hurley S, Varo N et al. Family history of diabetes is a major determinant of endothelial function. Journal of the American College of Cardiology. 2006. June 20;47(12):2456-61. 8. Gruden G, Cavallo-Perin P, Olivetti C, Repetti E, Sivieri R, Bruno A, Pagano G. Albumin excretion rate levels in non-diabetic offspring of NIDDM patients with and withoutnephropathy. Diabetologia. 1995. Oct 1;38(10):1218-22. 9. Hasan M, Mohieldein AH, Almutairi FR. Comparative study of serum 8-hydroxydeoxyguanosine levels among healthy offspring of diabetic and non-diabetic parents. International Journal of Health Sciences. 2017. Jul;11(3):33. 10. Refaat R, Abdelhameed AM, Elbarbary NS, El-Hilaly RA. Evaluation of median nerve in children with type1 diabetes using ultrasonographic imaging and electrophysiology. The Egyptian Journal of Radiology and Nuclear Medicine. 2013. September 30;44(3):563-72. 11. Said G. Diabetic neuropathy-a review. Nature clinical practice Neurology. 2007. June 1;3(6):331-40. 12. American Diabetes Association. Diagnosis and classification of diabetes mellitus. Diabetes care. 2004 Jan 1;27 (suppl 1). S.5-10. 13. Chakdoufi, S., Moumen, A., & Guerboub, A. Dyslipidemia and Diabetic Retinopathy in Moroccans Type 2 Diabetics Patients: A Cross-Sectional Study. Jour Med Resh and Health Sci, 2023;6(3):2471–2479. https://doi.org/10.52845/ Jmrhs/2023-6-3-1 14. Brownlee M. The pathobiology of diabetic complications. Diabetes. 2005 June 1;54 (6):1615-25. 15. Sharma VK, Joshi MV, Vishnoi AA. Interrelation of retinopathy with peripheral neuropathy in diabetes mellitus. Journal of Clinical Ophthalmology and Research. 2016. May 1;4(2):83. 16. Daube JR, Rubin DI. Nerve conduction studies. //Aminoff's Electrodiagnosis in Clinical Neurology. 6th ed. China: Elsevier Saunders Inc., 2012: 2906. 17. Sugimoto K, Yasujima M, Yagihashi S. Role of advanced glycation end products in diabetic neuropathy. Current pharmaceutical design. 2008. April 1;14(10):953-61. 18. Vague P, Dufayet D, Coste T, Moriscot C, Jannot MF, Raccah D. Association of diabetic neuropathy with Na/K ATPase gene polymorphism. Diabetologia. 1997. April 1; 40(5):506-11. 19. Gaulton KJ. Mechanisms of type 2 diabetes risk loci. Current diabetes reports. 2017. Sep 1; 17(9):72. 20. Garg R, Kumar A, Dhar U. A Study of Median Nerve Conduction Velocity in Diabetes Mellitus Type 2 in Neurologically Asymptomatic Patients. International Journal of Health Science and Research. 2013; 3(5):42-9.