Litcius/Paper detail

Antidiabetic Close Loop Based on Wearable DNA–Hydrogel Glucometer and Implantable Optogenetic Cells

Tiantian Man, Guiling Yu, Fulin Zhu, Yaqi Huang, Yueyu Wang, Yan Su, Shengyuan Deng, Hao Pei, Li Li, Haifeng Ye, Ying Wan

2024JACS Au13 citationsDOIOpen Access PDF

Abstract

Diabetes mellitus and its associated secondary complications have become a pressing global healthcare issue. The current integrated theranostic plan involves a glucometer-tandem pump. However, external condition-responsive insulin delivery systems utilizing rigid glucose sensors pose challenges in on-demand, long-term insulin administration. To overcome these challenges, we present a novel model of antidiabetic management based on printable metallo-nucleotide hydrogels and optogenetic engineering. The conductive hydrogels were self-assembled by bioorthogonal chemistry using oligonucleotides, carbon nanotubes, and glucose oxidase, enabling continuous glucose monitoring in a broad range (0.5-40 mM). The optogenetically engineered cells were enabled glucose regulation in type I diabetic mice via a far-red light-induced transgenic expression of insulin with a month-long avidity. Combining with a microchip-integrated microneedle patch, a prototyped close-loop system was constructed. The glucose levels detected by the sensor were received and converted by a wireless controller to modulate far-infrared light, thereby achieving on-demand insulin expression for several weeks. This study sheds new light on developing next-generation diagnostic and therapy systems for personalized and digitalized precision medicine.

Topics & Concepts

OptogeneticsWearable computerWearable technologyNanotechnologyBiomedical engineeringChemistryMaterials scienceComputer scienceNeuroscienceMedicineEmbedded systemBiologyPhotoreceptor and optogenetics researchMolecular Communication and NanonetworksNeuroscience and Neural Engineering