By: Seethaladevi .
Diabetes mellitus is a chronic metabolic disorder that necessitates continuous glucose monitoring and precise insulin delivery for effective management. Traditional methods often fall short in maintaining the necessary levels of accuracy and convenience, thereby posing challenges in achieving optimal glycemic control. Nanotechnology-enabled biosensors have revolutionized this field by leveraging the unique properties of nanomaterials, offering significant improvements in sensitivity, selectivity, and biocompatibility. This article delves deeply into the transformative role of nanotechnology in developing advanced biosensors specifically designed for continuous glucose monitoring and insulin delivery. The discussion begins with an exploration of enzymatic and non-enzymatic glucose biosensors. Enzymatic glucose biosensors typically employ glucose oxidase or glucose dehydrogenase, which facilitate the oxidation of glucose, producing measurable signals that are directly proportional to glucose concentrations. In contrast, non-enzymatic glucose biosensors capitalize on the properties of nanomaterials such as metal nanoparticles, carbon nanotubes, and graphene. These materials interact directly with glucose molecules, offering advantages such as enhanced stability and a longer shelf-life. Additionally, the article investigates nanostructured platforms designed for insulin monitoring and controlled delivery. These platforms include nanocarriers like liposomes, polymeric nanoparticles, and dendrimers, which protect insulin from degradation and enable targeted, sustained release. Some of these nanocarriers are engineered to respond to specific physiological stimuli, such as pH or glucose levels, allowing for on-demand insulin release that maintains optimal blood glucose levels. The integration of these advanced biosensors with closed-loop systems and artificial intelligence (AI) is another focal point. Closed-loop systems, also known as artificial pancreas systems, automate the monitoring of glucose levels and the delivery of insulin, thereby closely mimicking the body’s natural regulatory mechanisms. AI algorithms further enhance these systems by analyzing continuous data streams, predicting glucose trends, and adjusting insulin doses in real-time.
Keywords: Nanotechnology, biosensors, continuous glucose monitoring, insulin delivery, diabetes
management, closed-loop systems, Artificial Intelligence
Citation:
Refrences:
1.Ware J, Hovorka R. Closed-loop insulin delivery: update on the state of the field and emerging technologies. Expert Rev Med Devices. 2022;19(11):859-875.
2.Eswaran U, Eswaran V, Sudharshan VB. Human like biosensor disease simulator, disease analyzer and drug delivery system. In: 2013 IEEE Conference on Information and Communication Technologies, ICT 2013. 2013. p. 1033-1038.
3.Boland E, Monsod T, Delucia M, Brandt CA, Fernando S, Tamborlane WV. Limitations of conventional methods of self-monitoring of blood glucose: lessons learned from 3 days of continuous glucose sensing in pediatric patients with type 1 diabetes. Diabetes Care. 2001;24(11):1858-1862.
4. Johnston L, Wang G, Hu K, Qian C, Liu G. Advances in biosensors for continuous glucose monitoring towards wearables. Frontiers in bioengineering and biotechnology. 2021 Aug 19;9:733810.
5. Reddy M, Oliver N. The role of real‐time continuous glucose monitoring in diabetes management and how it should link to integrated personalized diabetes management. Diabetes Obes Metab. 2024;26:46-56.
6. Ushaa SM, Madhavilatha M, Rao GM. Design and analysis of nanowire sensor array for prostate cancer detection. Int J Nano Biomater. 2011;3(3):239-255.
7. Manna AK, Ray SK, Saha H, Gangopadhyay U. Non-enzymatic glucose sensors based on electrodeposited CuxO–ZnO composite nanostructures. J Mater Sci Mater Electron. 2024;35(2):1-12.
8. Shaghaghi Z, Shalghuni AS, Jafari S. Fe2O3/CuO Hybrid Nanostructures as Electrode Materials for Glucose Detection. Anal Bioanal Chem Res. 2024;11(3):343-360.
9. Rasheed S, Yan Y, Abdalla AN, Zhang Q, Zhang L. Advances and challenges in portable optical biosensors for onsite detection and point-of-care diagnostics. TrAC Trends Anal Chem. 2024;117640.
10. Guo L, Zhang X, Jiang X, Liu Z, Huang L, Song S, et al. DNA tetrahedral nanostructure-corbelled DNA walker for intramolecular electrochemiluminescence resonance energy transfer sensing of tumor exosomes. Sens Actuators B Chem. 2024;410:135735
11.Shi Y, Li X, Wang Y, Li J, Zhang H, Tang B. Tailored Drug Delivery Platforms: Stimulus‐Responsive Core–Shell Structured Nanocarriers. Adv Healthc Mater. 2024;13(1):2301726.
12.Eswaran U, Khang A, Eswaran V. Applying machine learning for medical image processing. In: AI and IoT-Based Technologies forPrecision Medicine. 2023. p. 137-154.
13.Gill R, Pandey A, Lakhmani A, Mathur M. Predicting Consumer. In: Software-Defined Network Frameworks: Security Issues and Use Cases. 2024. p. 68.
14.Nimri R, Bergenstal R, Weinzimer S, Liljenquist D, Bailey T. Closed-Loop Control, Artificial Intelligence–Based Decision-Support Systems, and Data Science. Diabetes Technol Ther. 2024;26(S1):S-68.
15.Eswaran U, Eswaran V, Murali K, Eswaran V. Healthcare smart sensors: Applications, trends, and future outlook. In: Driving Smart Medical Diagnosis Through AI-Powered Technologies and Applications. 2024. p. 24-48.
16.Yi K, Hu S, Wang J, Li P, Ren X. Semi-interpenetrating network hydrogels-based microcapsule for quorum quenching bacteria biocontainment to enhance biofouling control in membrane bioreactor. Chem Eng J. 2024;486:150103.
17. Nakua H, Hrybouski S, Wong BW, Martinez TR, Rogers SM, Becker S. Comparing the stability and reproducibility of brain-behaviour relationships found using Canonical Correlation Analysis and Partial Least Squares within the ABCD Sample. Netw Neurosci. 2024;1-52.
18. Dang C, Zhang X, Song H, Yang J, Chen Z. Structure integration and architecture of solar-driven interfacial desalination from miniaturization designs to industrial applications. Nat Water. 2024;2(2):115-126.
19. Eswaran U, Khang A. Augmented Reality (AR) and Virtual Reality (VR) Technologies in Surgical Operating Systems. In: AI and IoT Technology and Applications for Smart Healthcare Systems. 2024. p. 113-129.
20. Vo TS, Nguyen TX, Dang TM, Pham HT, Le TD, Tran TT, et al. Recent Trends of Bioanalytical Sensors with Smart Health Monitoring Systems: From Materials to Applications. Adv Healthc Mater. 2024;2303923
