Litcius/Paper detail

Aqueous Grown Quantum Dots with Robust Near-Infrared Fluorescence for Integrated Traumatic Brain Injury Diagnosis and Surgical Monitoring

Mingxia Jiao, Xiaoqi Li, Hui Liu, Peng Cai, Xiling Yang, Kevin J. McHugh, Bowen Zheng, Jiachen Sun, Peisen Zhang, Xiliang Luo, Lihong Jing

2024ACS Nano25 citationsDOI

Abstract

Surgical intervention is the most common first-line treatment for severe traumatic brain injuries (TBIs) associated with high intracranial pressure, while the complexity of these surgical procedures often results in complications. Surgeons often struggle to comprehensively evaluate the TBI status, making it difficult to select the optimal intervention strategy. Here, we introduce a fluorescence imaging-based technology that uses high-quality silver indium selenide-based quantum dots (QDs) for integrated TBI diagnosis and surgical guidance. These engineered, poly(ethylene glycol)-capped QDs emit in the near-infrared region, are resistant to phagocytosis, and importantly, are ultrastable after the epitaxial growth of an aluminum-doped zinc sulfide shell in the aqueous phase that renders the QDs resistant to long-term light irradiation and complex physiological environments. We found that intravenous injection of QDs enabled both the precise diagnosis of TBI in a mouse model and, more importantly, the comprehensive evaluation of the TBI status before, during, and after an operation to distinguish intracranial from superficial hemorrhages, provide real-time monitoring of the secondary hemorrhage, and guide the decision making on the evacuation of intracranial hematomas. This QD-based diagnostic and monitoring system could ultimately complement existing clinical tools for treating TBI, which may help surgeons improve patient outcomes and avoid unnecessary procedures.

Topics & Concepts

Traumatic brain injuryQuantum dotMedicineIntracranial pressureSurgeryIntensive care medicineNanotechnologyBiomedical engineeringMaterials sciencePsychiatryTraumatic Brain Injury and Neurovascular DisturbancesNanoplatforms for cancer theranosticsCerebrospinal fluid and hydrocephalus