Alveoli-Like Multifunctional Scaffolds for Optical and Electrochemical In Situ Monitoring of Cellular Responses from Type II Pneumocytes.
Seonghyeon EomSo Yeon LeeJung Tae ParkInhee ChoiPublished in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2023)
While breathing, alveoli are exposed to external irritants, which contribute to the pathogenesis of lung disease. Therefore, in situ monitoring of alveolar responses to stimuli of toxicants under in vivo environments is important to understand lung disease. For this purpose, 3D cell cultures are recently employed for examining cellular responses of pulmonary systems exposed to irritants; however, most of them have used ex situ assays requiring cell lysis and fluorescent labeling. Here, an alveoli-like multifunctional scaffold is demonstrated for optical and electrochemical monitoring of cellular responses of pneumocytes. Porous foam with dimensions like the alveoli structure is used as a backbone for the scaffold, wherein electroactive metal-organic framework crystals, optically active gold nanoparticles, and biocompatible hyaluronic acid are integrated. The fabricated multifunctional scaffold allows for label-free detection and real-time monitoring of oxidative stress released in pneumocytes under toxic-conditions via redox-active amperometry and nanospectroscopy. Moreover, cellular behavior can be statistically classified based on fingerprint Raman signals collected from the cells on the scaffold. The developed scaffold is expected to serve as a promising platform to investigate cellular responses and disease pathogenesis, owing to its versatility in monitoring electrical and optical signals from cells in situ in the 3D microenvironments.
Keyphrases
- label free
- metal organic framework
- tissue engineering
- gold nanoparticles
- induced apoptosis
- oxidative stress
- hyaluronic acid
- drug delivery
- cell cycle arrest
- high resolution
- cancer therapy
- single cell
- high throughput
- high speed
- pulmonary hypertension
- cell therapy
- cell death
- quantum dots
- ischemia reperfusion injury
- single molecule
- reduced graphene oxide
- mass spectrometry
- highly efficient
- room temperature
- solid phase extraction