Current Nanomedicine

2468-18732468-1881

Bentham Science

675845

10.2174/0124681873265152231229042106

Pharmacology

Research Article

A Systematic Review on the Potential Applications of Theranostic Nanoparticles in Diabetes and its Associated Complication Diabetic Neuropathy

Patangia

Uddhav

info@benthamscience.netBhatta

Kalpita

info@benthamscience.netVig

Himangi

info@benthamscience.netPriya

Sneh

info@benthamscience.netWal

Ankita

info@benthamscience.netTyagi

Lalit

info@benthamscience.netWal

Pranay

info@benthamscience.net

Department of Pharmacy, Girijananda Chowdhury Institute of Pharmaceutical Science -TezpurSchool of Applied Sciences, Centurion University of Technology and ManagementDepartment of Pharmacy, Panveer Singh Institute of TechnologyNGSM Institute of Pharmaceutical Science, Nitte (Deemed to be University), Lloyd Institute of Management and Technology

01032024

143

24726528022025

2024

Bentham Science Publishers

https://journals.eco-vector.com/2468-1873/article/view/675845

Background:Diabetes neuropathy is a frequent ailment that has a substantial impact on patients by increasing the risk of falls and causing discomfort. The lower extremities are where diabetic neuropathy patients first feel pain. This discomfort could seem like a pinprick, an electric shock, or something else.

Objective:Here, we give a comprehensive overview of this quickly developing theranostic appli-cation that includes all relevant imaging, diagnostic, therapeutic, and monitoring elements for the management of diabetes and diabetes neuropathy.

Methods:The data for the current study was gathered by searching PubMed and Google Scholar. Several research and review publications from various publishers, including Springer Nature, Bentham Science, PLOS one, MDPI, and ACS Publishing Centre, were evaluated to compile the data.

Result:Recent developments in theranostics have shown promise as alternate management ap-proaches for diabetes and ailments linked to diabetes. Numerous nanotechnology-built biosen-sors, including multiwalled carbon nanotubes, copper nanowires, zinc oxide tetrapods, and nano-particle-embedded contact lenses, offer benefits in monitoring diabetic neuropathy.

Conclusion:The potency, usability, and dependability of insulin substitutes have been demon-strated by a variety of innovative methods for the management of diabetes, which includes nano-technology approaches using Gene-Based Nanoparticles (siRNA), Liposomes, Exo-somes/Extracellular Vesicles, Neuromodulation, and Inhalable Nanoparticles. Over the past few years, the development of various theranostic nanoparticles for Diabetic neuropathy has experi-enced an unprecedented expansion. Even though much work needs to be done to precisely evalu-ate the genuine benefits provided by these particles, such as issues with nanotoxicity, theranostic nanoparticles will have a significant impact on the field of nanomedicine.

Diabetes neuropathytheranosticsnanotechnologynanoparticlesinhalable nanoparticlesmultiwalled carbon nanotubes.

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