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Designing smart (bio)interfaces with the capability to sense and react to changes in local environments offers intriguing possibilities for new surface-based sensing devices and technologies. Polymer brushes make ideal materials to design such adaptive and responsive interfaces given their large variety of functional and structural possibilities as well as their outstanding abilities to respond to physical, chemical, and biological stimuli. Herein, a practical sensory interface for glucose detection based on auto-fluorescent polymer brushes decorated with phenylboronic acid (PBA) receptors is presented. The glucose-responsive luminescent surfaces, which are capable of translating conformational transitions triggered by pH variations and binding events into fluorescent readouts without the need for fluorescent dyes, are grown from both nanopatterned and non-patterned substrates. Two-photon laser scanning confocal microscopy and atomic force microscopy (AFM) analyses reveal the relationship between the brush conformation and glucose concentration and confirm that the phenylboronic acid functionalized brushes can bind glucose over a range of physiologically relevant concentrations in a reversible manner. The combination of auto-fluorescent polymer brushes with synthetic receptors presents a promising avenue for designing innovative and robust sensing systems, which are essential for various biomedical applications, among other uses. 

Abstract Designing smart (bio)interfaces with the capability to sense and react to changes in local environments offers intriguing possibilities for new surface‐based sensing devices and technologies. Polymer brushes make ideal materials to design such adaptive and responsive interfaces given their large variety of functional and structural possibilities as well as their outstanding abilities to respond to physical, chemical, and biological stimuli. Herein, a practical sensory interface for glucose detection based on auto‐fluorescent polymer brushes decorated with phenylboronic acid (PBA) receptors is presented. The glucose‐responsive luminescent surfaces, which are capable of translating conformational transitions triggered by pH variations and binding events into fluorescent readouts without the need for fluorescent dyes, are grown from both nanopatterned and non‐patterned substrates. Two‐photon laser scanning confocal microscopy and atomic force microscopy (AFM) analyses reveal the relationship between the brush conformation and glucose concentration and confirm that the phenylboronic acid functionalized brushes can bind glucose over a range of physiologically relevant concentrations in a reversible manner. The combination of auto‐fluorescent polymer brushes with synthetic receptors presents a promising avenue for designing innovative and robust sensing systems, which are essential for various biomedical applications, among other uses. 

Abstract We present a versatile platform for fabricating two‐photon excitable carbon dot‐based nanocomposite thin films by harnessing the structural versatility of polymer brushes in combination with electron‐beam lithography (EBL). This approach enables the precise spatial organization of carbon dots (CDs) at the nanoscale, facilitating dynamic modulation of their photoluminescent properties in response to environmental stimuli. Three model systems were examined, incorporating pH‐ and thermally responsive polymers, functionalized through covalent and dynamic covalent bonding strategies. By leveraging the spatial control afforded by nanostructured polymer brushes, we achieved precise tuning of optical properties while mitigating aggregation‐induced quenching, a longstanding challenge in solid‐state CD applications. In addition to the advances in controlling optical properties, this work highlights the potential of polymer brush systems to function as optically active, reprogrammable surfaces. The resulting nanoscale‐engineered materials exhibit highly responsive, reconfigurable photonic behavior, offering a scalable pathway for integrating advanced optical interfaces into microchip technologies, biosensing platforms, and multiplexed diagnostic systems. The fusion of polymer brushes, carbon dots, and advanced lithographic techniques marks a substantial advancement in the development of functional materials with nanoscale precision and stimuli‐responsive properties. 

Introducing functionality onto PE surfaces is a longstanding challenge in polymer science, driven by the need for polymer materials with improved adhesion and antifouling properties. Herein, we report surface-initiated hydrogen atom transfer-reversible addition−fragmentation chain transfer(SI HAT RAFT) as a robust method to grow high-density brush polymers from PE surfaces.