Table 1.
Summary of the current progress of AIEgen-based nanomaterials for bacterial imaging, detection, and therapy.
| Serial Number | Type of Nanomaterial | Protocol | Application | Reference |
|---|---|---|---|---|
| 1 | Nanoparticle of polymer-based NIR-II AIEgens (PDTPTBT) | NIR-II imaging-guided PTT | Subcutaneous abscess and diabetic skin infection | [60] |
| 2 | Polymeric antimicrobial catiomer-based AIEgens | Electrostatic interaction | Biodegradable antibacterial agents and bacterial detection | [62] |
| 3 | Zwitterionic polymer nanoparticle-based AIEgens | Inactivation of bacteria by generating ROS under acidic conditions | Antibacterial under acidic infection sites | [112] |
| 4 | AIE nanoparticle by self-assembly | PTT and PDT of pathogens by producing 1O2 and heat | Accelerate S. aureus-infected wound healing | [125] |
| 5 | Nanomaterial based on MSNs loading AMO, PGEDA, and TPE-(COOH)4 | Bacterial imaging and antibacterial action with TPE-(COOH)4 and release of AMO | Antibacterial and bacterial detection | [126] |
| 6 | Nanoparticles with loading ciprofloxacin and AIEgens | Accurate delivery of antibiotics and dynamic monitoring | Intracellular bacterial infection | [73] |
| 7 | Organosilica nanoparticles loading rifampicin and NIR AIEgens | Imaging-guided synergistic photodynamic/antibiotic therapy | Bacterial imaging and killing | [77] |
| 8 | Ciprofloxacin-based nanodrugs with AIE | Bacterial imaging and antibacterial action with AIE-active luminogens and drugs | Combating drug-resistant bacterial infections | [127] |
| 9 | AIE-active probe based antimicrobial peptide (AMPs) | Real-time monitoring bactericidal process | Investigation of the bactericidal mechanism of AMPs | [98] |
| 10 | AIEgen-peptide-based fluorescent bioprobe specific to caspase-1 | Caspase-1 activation and bacteria killing with ROS | Detection and elimination of intracellular bacteria | [90] |
| 11 | Human defensin-6 mimic peptide (HDMP) based AIEgens | Bacteria are trapped by fibrous networks and monitoring | MRSA-induced bacteraemia | [95] |
| 12 | MIL-100 (Fe) nanoparticles loading D-AzAla | Bacteria metabolic labelling and precise bacteria killing with PD | Precise bacterial detection and therapy | [98] |
| 13 | Conjugating gold nanoclusters and daptomycin | Destroy the bacterial membrane and DNA with daptomycin and ROS | MDR bacterial infection | [104] |
| 14 | A tetraphenylethylene-based discrete organoplatinum (II) metallacycle | Photodynamic inactivation with ROS generation and strong membrane-intercalating ability | Control of bacterial infections, especially for Gram-negative bacteria | [128] |
| 15 | AIE bioconjugate-based phage | Specifically targets, infects, and kills bacteria via phages and ROS | Antibiotic-sensitive and MDR bacteria-infected wounds | [113] |
| 16 | AIEgen intercalated nanoclay-based | Photodynamic/chemodynamic theranostics by generating 1O2 and •OH | P. aeruginosa-infected subcutaneous wounds | [81] |
| 17 | Peptide-engineered AIE nanofibers | Synergistic antibacterial activities of the ROS and peptides | Precise adjustment of antibacterial activities and bacterially infected wound healing | [124] |
| 18 | AIEgen-loaded nanofibrous membrane | Sunlight-triggered photodynamic/photothermal antipathogen | Interception of pathogenic droplets and aerosols | [129] |
| 19 | Nanoparticles-based nanographene oxide and AIEgen | Photothermal/photodynamic synergistic antibacterial | Bacterial tracer and killer | [130] |