Aggregation-Induced Emission: New Vistas at the Aggregate Level

Aggregation-induced emission-based aptasensors for the detection of various targets: Recent progress

The advancement of aptasensors utilizing aggregation-induced emission (AIE) has progressed remarkably in recent years, owing to various unique benefits provided by aggregation-induced emission luminogens (AIEgens) as a novel category of fluorescent substances and aptamers as exceptional recognition components. AIE refers to a photophysical phenomenon identified in certain luminogens that show minimal or absent emission in dilute solutions, yet display considerable emission when in aggregate or solid states. Fluorescent sensing is an effective technique for the detection of various targets; however, many traditional dyes frequently demonstrate an aggregation-caused quenching (ACQ) effect in solid form, which limits their applicability on a larger scale. In contrast, fluorescent probes that leverage AIE characteristics have garnered considerable interest, owing to their elevated fluorescence quantum yields and ease of fabrication. This review discusses the application of various AIEgens in the design of diverse sensitive and selective AIE-based aptasensors for monitoring various targets, with a particular focus on recent advances. The AIE-based aptasensors exploit the supreme affinity of the aptamers to their targets and the remarkable properties of AIEgen, including its photostability and high quantum yield, and the interaction between AIEgen and DNA. The objective is to acquaint researchers with the various categories of materials exhibiting AIE characteristics and their potential applications in the creation of different aptasensors, enabling them to introduce novel kinds of innovative AIEgens and AIE-integrated aptasensors.

Tricarbonylrhenium(I) complexes with aggregation-induced phosphorescence emission (AIPE) properties: Application to the selective detection of heparin and its main contaminant

Phosphorescent tricarbonylrhenium(I) complexes that are more emissive in the aggregate state than in solution could be very valuable probes for biological analyses, but their development is delicate. The present work focuses on the synthesis and spectroscopic study of three new complexes that differ by the nature of their positively charged substituent. The dissolved complexes were very weakly emissive. Due to electrostatic interaction and aggregation, they showed a strong aggregation-induced phosphorescence enhancement (AIPE) effect in the presence of heparin, a polyanionic macromolecule of biological interest, and a weaker effect in the presence of chondroitin sulfate, which contains fewer negative charges. The magnitude of the AIPE effect depended on the nature and number of the cationic groups borne by the complex. However, it was weaker than expected from the behavior of the parent neutral complex studied in a conventional acetonitrile/water system, which highlights the challenge of accurately predicting solid-state emission properties for this class of molecules. This work introduces rhenium(I) complexes in the field of AIPE-active probes for the detection of polyanionic biomolecules.

Molecularly manipulating pyrazinoquinoxaline derivatives to construct NIR-II AIEgens for multimodal phototheranostics of breast cancer bone metastases

Multimodal phototheranostics on the basis of single molecular species shows inexhaustible and vigorous vitality, particularly those emit fluorescence in the second near-infrared window (NIR-II), the construction of such exceptional molecules nonetheless retains formidably challenging. In view of the undiversified molecular skeletons and insufficient phototheranostic outputs of previously reported NIR-II fluorophores, herein, electron acceptor engineering based on heteroatom-inserted rigid-planar pyrazinoquinoxaline was manipulated to fabricate aggregation-induced emission (AIE)-featured NIR-II counterparts with donor-acceptor-donor (D-A-D) architecture. Systematical investigations substantiated that one of those synthesized AIE molecules, namely 4TPQ, incorporating a fused thiophene acceptor, synchronously exhibited high molar absorptivity (ε), NIR-II emission, typical AIE tendency, significant reactive oxygen species (ROS) generation, and high photothermal conversion efficiency. These extraordinary behaviors endowed 4TPQ nanoparticles with unprecedented performance on NIR-II fluorescence/photothermal imaging-navigated synergistic photodynamic/photothermal inhibition of tumors, as confirmed by the mice model of breast cancer bone metastases. This study thus brings significant insights into developing phototheranostic systems for clinical trials.

Aggregation-induced emission-twisted intramolecular charge transfer-activated fluorescent probe for analyzing mitochondrial viscosity in cells and zebrafish

Mitochondria are crucial energy-supplying organelles that support cellular activities and play vital roles in cell metabolism, aging, autophagy, and apoptosis. Abnormal viscosity can alter the mitochondrial microenvironment, disrupt normal mitochondrial function, and lead to disease. To address this, we designed and developed two aggregation-induced emission-twisted intramolecular charge transfer fluorescent probes, namely, (E)-1,1,3-trimethyl-2-(4-(1,2,2-triphenylvinyl)styryl)-1H-benzo[e]indol-3-ium (HSL-1) and (E)-2-(4-(di-p-tolylamino)styryl)-1,3,3-trimethyl-1H-benzo[e]indol-3-ium (HSL-2). In vitro fluorescence detection revealed that both HSL-1 and HSL-2 were sensitive to viscosity and demonstrated a strong log-linear relationship, with linear coefficients of 0.982 and 0.980, respectively. Notably, the responses of HSL-1 and HSL-2 to viscosity changes were unaffected by pH, polarity, or interfering ions. HSL-1 exhibited stronger resistance to background interference than HSL-2 and significantly enhanced fluorescence intensity; thus, it was selected for cell experiments and animal fluorescence intensity assessments. Furthermore, HSL-1 showed excellent biocompatibility, enabling real-time detection of mitochondrial viscosity changes and identification of viscosity abnormalities triggered by mitophagy in HeLa cells. It could also monitor changes in mitochondrial viscosity in zebrafish. In conclusion, HSL-1 is a valuable tool for studying viscosity and understanding diseases associated with abnormal mitochondrial viscosity.

Self-recoverable elastico mechanoluminescence of a hybrid metal halide crystal

Materials exhibiting self-recoverable elastico mechanoluminescence (EML) are highly sought after due to their utility in sensing and information encryption. However, the current pool of identified EML materials remains limited, exclusively comprising purely inorganic substances. This study delves into the investigation of the EML properties of a zero-dimensional (0D) organic-inorganic metal halide denoted as [C19H18P]2MnBr4 (where C19H18P+ signifies methyl triphenyl phosphonium). Notably, [C19H18P]2MnBr4 manifests two distinct polymorphs, with the piezoelectric and non-piezoelectric polymorphs exhibiting thermodynamic and kinetic stability, respectively. Despite both compounds showing bright greenish luminescence, only the piezoelectric phase exhibits desirable EML behavior. The EML in this context is distinguished by its high intensity, strong fatigue resistance and prompt self-recovery. The underlying mechanism of EML in the piezoelectric polymorph can be explained by the piezoelectric effect and the stress-induced energy band tilting. Calorimetric and piezoelectric experiments reveal the self-recoverable EML arises from the relaxation of the stress-induced kinetically stable non-piezoelectric to the thermodynamically favored piezoelectric phase. This work paves a new pathway in the exploration of self-recoverable EML materials in the realm of hybrid organic-inorganic crystals.

Thioflavin T Inspirations: On the Photophysical and Aggregation Properties of Fluorescent Difluoroborates Based on the Benzothiazole Core

In this work, we investigated a novel series of fluorescent dyes based on benzothiazole core substituted with a palette of donor groups that differ in size, shape, and character (alkyl vs aromatic). These dyes exhibit an intramolecular charge transfer state in their electronic structure. The photophysical properties of the newly synthesized dyes were studied with an eye toward aggregation effects in solvents and mixtures of solvents differing in polarity. Moreover, multiphoton absorption studies were performed to determine the potential of the dyes in two-photon microscopy. The results of spectroscopic measurements were supported by electronic structure calculations using coupled-cluster theory. Overall, the results provide an indication regarding the optimal substituents to achieve bright emission in various media and how these properties are related to aggregation effects.

Dipyrroethene-Based Red-Light Emissive AIEgens

Aggregation-induced emission (AIE) molecules find myriads of applications in various fields ranging from biomedical probes and chemical sensors to optoelectronics. In this domain, tetraphenylethene (TPE) and its derivatives have long been a benchmark due to their unique luminescent properties in aggregated states. However, the limited tunability through further functionalization and the absorption and emission spectrum in higher-energy regions constrain their applications from multiple domains. To address these limitations, we have designed a new class of highly symmetric red-light emissive AIE-active molecules by structurally engineering the E-dipyrroethene (DPE) skeleton. This design enables pre- and postsynthetic modification opportunities through the two pyrrole rings and multiple heteroatoms, facilitating tunable photophysical properties. In this context, DPE-based AIEgens Tz and BTz were synthesized through the selective α,α-diformylation of DPE followed by condensation with 2-aminothiazole and 2-aminobenzothiazole, respectively. The π-extended conjugation systems in Tz and BTz containing multiple heteroatoms tune the excitation spectra in visible wavelength and emission spectra above 600 nm with a large Stokes shift in the range of 3632-5058 cm-1. Moreover, this modification provides a great platform for numerous noncovalent interactions, which significantly enhance aggregation- and solid-state fluorescence properties. Furthermore, various experimental, spectroscopic, and theoretical studies and X-ray crystallography measurements elucidate the structure-property relationships of these molecules, which pave the way for the development of novel materials with various applications in sensing and bioimaging. As a proof of concept, the potential of these molecules has been successfully demonstrated for the development of vapor- and solution-phase dynamic acid-base stimuli-responsive smart sensors, as well as the application of the BTz molecule in live-cell imaging.

Preparation and Mechanism Insight of Biodegradable Kippah Vesicles

Kippah vesicles, fully collapsed polymersomes formed during the self-assembly process, are characterized by a bowl-shaped nanostructure with a large specific surface area, high loading capacity, and an internal void. Current research shows that these structural features have primarily been achieved using non-biodegradable block copolymers, while the fundamental mechanism behind their formation is not well understood. Thus, designing biodegradable kippah vesicles and elucidating their formation mechanism is critical. In this study, a tetraphenylethylene (TPE) moiety - a luminogen with aggregation-induced emission (AIE) properties - is strategically introduced into the block copolymer side chain-, yielding the novel polypeptide poly(ethylene glycol)45-block-poly[(glutamic acid-TPE)26-stat-(glutamic acid)29] [PEG₄₅-b-P(GATPE₂₆-stat-GA₂₉)]. This polypeptide could self-assemble into kippah vesicles driven by hydrophobic interactions and hydrogen bonding, as confirmed by Fourier-transform infrared (FTIR) spectroscopy, ultraviolet-visible (UV-vis) absorption, photoluminescence spectroscopy, and morphological characterization across different aggregation states. Notably, the intrinsic fluorescence of these kippah vesicles exhibited high cellular internalization efficiency and excellent cytocompatibility, highlighting their potential for biomedical applications such as bioimaging and targeted cellular delivery.

Rh-catalyzed mechanochemical transfer hydrogenation for the synthesis of periphery-hydrogenated polycyclic aromatic compounds

Hydrogenated nanographene has attracted attention as a new class of nanocarbon material owing to its potential applications in various research fields. However, the synthesis of periphery-hydrogenated nanographenes or polycyclic aromatic hydrocarbons (PAHs) is a significant challenge because of the harsh conditions and poor solubility of the starting materials. Conventional solution-state conditions require high-pressure hydrogen gas and lengthy reaction times. In this study, we developed a novel approach utilizing rhodium-catalyzed mechanochemical transfer hydrogenation, which enables hydrogenation without using hydrogen gas. Various hydrogenated PAHs were rapidly obtained using a simple protocol under ambient atmosphere and air, with one PAH showcasing intriguing properties such as aggregation-induced emission. Thus, the demonstrated mechanochemical hydrogenation method is expected to contribute to the rapid and efficient synthesis of a novel class of sp2/sp3-carbon-conjugated hydrocarbons.

Multiscale Structural Analysis of Aggregation-Induced Emission Nanocrystals by Combining Electron and Confocal Microscopy

Aggregation-induced emission (AIE) materials have attracted intense interest due to their remarkable luminescent properties and potential applications in biological and medical fields. A comprehensive structural analysis from atomic-level to micrometer-scale is essential for rationally designing AIE materials and understanding their structure-property relationships. However, this remains a challenge due to the lack of proper methods. Herein, we present a strategy for multiscale structural analysis of AIE materials through a combination of electron and confocal microscopy. One mechanically induced fluorescent AIE material consisting of a chiral Au(I) complex was prepared and studied. The correlation of scanning electron and optical microscope images reveals that the fluorescence is closely related to the anisotropy of nanocrystals with strong signals on fracture {110} facets. Furthermore, instead of growing large single crystals, atomic-level crystal structures of individual nanocrystals were directly resolved using three-dimensional electron diffraction (3D ED), highlighting the changes in molecular arrangement before and after mechanical treatment. The results provide experimental evidence for the previously proposed mechanically induced Restriction of Intramolecular Rotation (RIR) mechanism.

Noncovalent Interaction-Based Probe Design for PET-Facilitated Fluorescence Sensing of Synthetic Cannabinoids

Due to the structural diversity and rapid iteration of synthetic cannabinoids (SCs), their detection presents a challenging issue. Here, based on the structure and physicochemical property analysis of a typical SC, MDMB-CHMICA, four fluorescent probes were designed by introducing the recognition groups and fluorescence regulation groups on carbazole. It is found that the electron-withdrawing and conjugation-extending effect of the nitro group reduced the LUMO energy level and thereby narrowed the HOMO-LUMO energy gap, resulting in a red-shift of the fluorescence emission. As a result, the intramolecular charge transfer mechanism of the probe helps to lead to stronger fluorescence with a greater charge transfer distance. Two probes with stronger fluorescence show multiple noncovalent interactions with MDMB-CHMICA and efficient fluorescence quenching sensing through photoinduced electron transfer. This study is expected to shed light on the exploration of fluorescent probes from the analytes' physicochemical nature and would be helpful for new psychoactive substance detection.

Optically active chiral photonic crystals exhibiting enhanced fluorescence and circularly polarized luminescence

Photonic crystals with advanced, unique and well-defined functional nanostructures demonstrate exquisite controllable modulation in light harvesting and emission for unrivalled optical performance. Herein, through ingeniously integrating aggregation-induced emission (AIE) luminogens and chiral helical media into ordered periodic structures, the resulting optically active photonic crystal films exhibit an enhanced photoluminescence (PL) characteristic (increased to 2.2 times the original value) and distinctive emerging circular dichroism (CD) responses near the photonic bandgap (PBG) of the photonic crystal. The modulation of the PL intensity and CD signal peak position is precisely achieved by regulating the PBG by facilely tuning the size of the colloidal nanoparticles. Such an interesting phenomenon is mainly the consequence of the PBG edge enhancement effect (including the slow photon effect) and bandgap separation arising from chirality. Remarkably, the boosted fluorescence facilitates the synergistic effect of valid chirality transfer among achiral AIEgens and chiroptical media in a photonic matrix, which effectively contributes to the enhanced circularly polarized luminescence (CPL) activity, thereby expanding the potential applications of CPL-based optically active photonic materials in circularly polarizing emitting devices.

Activatable Photosensitizers: From Fundamental Principles to Advanced Designs

Photodynamic therapy (PDT) is a promising treatment that uses light to excite photosensitizers in target tissue, producing reactive oxygen species and localized cell death. It is recognized as a minimally invasive, clinically approved cancer therapy with additional preclinical applications in arthritis, atherosclerosis, and infection control. A hallmark of ideal PDT is delivering disease-specific cytotoxicity while sparing healthy tissue. However, conventional photosensitizers often suffer from non-specific photoactivation, causing off-target toxicity. Activatable photosensitizers (aPS) have emerged as more precise alternatives, offering controlled activation. Unlike traditional photosensitizers, they remain inert and photoinactive during circulation and off-target accumulation, minimizing collateral damage. These photosensitizers are designed to "turn on" in response to disease-specific biostimuli, enhancing therapeutic selectivity and reducing off-target effects. This review explores the principles of aPS, including quenching mechanisms stemming from activatable fluorescent probes and applied to activatable photosensitizers (RET, PeT, ICT, ACQ, AIE), as well as pathological biostimuli (pH, enzymes, redox conditions, cellular internalization), and bioresponsive constructs enabling quenching and activation. We also provide a critical assessment of unresolved challenges in aPS development, including limitations in targeting precision, selectivity under real-world conditions, and potential solutions to persistent issues (dual-lock, targeting moieties, biorthogonal chemistry and artificial receptors). Additionally, it provides an in-depth discussion of essential research design considerations needed to develop translationally relevant aPS with improved therapeutic outcomes and specificity.

Rational design of hypochlorous acid-activatable fluorescent probe for diagnostic imaging and therapeutic evaluation in breast cancer recurrence

The recurrent breast cancer (BC) has elicited significant concern due to its rising recurrence rates and associated mortality. However, there is currently no effective detection method to mitigate the deterioration of BC recurrence. The imbalance of HClO content could lead to oxidative stress in the body, which damaging host tissues. Additional, improper regulation of HClO may exacerbate the progression of BC and promote the metastasis of BC cells. Accurately diagnosing and monitoring the HClO levels is crucial for treating BC recurrence. Traditional fluorescent probes for HClO exhibit several limitations, including poor selectivity, susceptibility to photobleaching, a small Stokes shift, and vulnerability to disturbances from excitation and fluorescence self-absorption, which undermine the precise detection of target analytes and restrict their biological applications. Herein, rational designed hypochlorous acid-activatable fluorescent probe (QPIO) was synthesized based on phenothiazine (PZ), quinoline malononitrile (QM), and hemicyanine, which demonstrated high anti-interference capability and a significant Stokes shift for HClO detection. Under various stimuli, QPIO was able to monitor HClO levels in RAW 264.7 and 4T1 cells in the red channel. Furthermore, it elucidated the correlation between HClO concentration and the progression of BC recurrence. Consequently, QPIO was utilized to diagnose recurrent BC, track therapeutic progress, and monitor the recurrence status of breast tumors in mouse models through in vivo HClO fluorescence imaging. It was demonstrated that a close relationship exists between the dynamic changes in HClO levels and BC recurrence, potentially advancing the understanding of the early diagnosis and development of therapeutic agents for recurrent BC.

Naphthalimide and Carbazole Based Mechanochromic Molecular Dyads and Triads for Selective Lysosome Imaging

In this study, we report the design and development of a stable fluorescent probe that is selectively localized in the cytosol of Hela cells. We designed two probes, 1 and 2, with D-π-A (carbazole (Cbz)-vinyl-naphthalimide (NPI)) and A-π-D-π-A (NPI-vinyl-Cbz-vinyl-NPI) architecture, respectively. Probes 1 and 2 exhibit broad photoluminescence (PL) spectra ranging from green (550 nm) to far-red (800 nm) in solutions and aggregated states. In the solid-state, the PL of these probes shows a bathochromic shift, which can be attributed to intermolecular interactions. In a water-rich medium, Probe 1, with a single NPI moiety, shows aggregation-caused quenching (ACQ) but retains a moderate quantum yield of 13.7 % (Φsoln=61.4 %). On the other hand, probe 2, with two NPI units, showed aggregation-induced enhanced emission AIEE, where the PLQY is increased nearly 4 times (Φsoln=3.5 %, Φagg=12.8 %). In-vitro cell studies revealed that these probes are non-toxic and effectively stain cells in green and red channels. Notably, Probe 1 demonstrated excellent cellular uptake and selectivity for lysosome, with a Pearson overlap coefficient of 0.91.

Crystallization-Induced Emission Enhancement or Quenching? Elucidating the Mechanism behind Using Single-Molecule-Based Versatile Crystals

It is challenging to predict optical properties of fluorescent dyes, especially in the crystalline state, owing to the uncertainty in conformation, packing, and coupling. Herein, we elucidate the decisive role of molecular conformation and molecular packing in the fluorescence emissions of some crystalline materials based on experimental results and theoretical calculations. Two homologous fluorophores (Ph-MP and Ph-HP) were synthesized, and they both exhibited interesting crystallization-induced emission enhancement and quenching. Although the homologues show almost the same fluorescence behavior in the solid state, on-off emission of their crystals depends upon different factors. Emission of the Ph-MP crystals is governed by the twisted intramolecular charge transfer effect, while emission of the Ph-HP crystals relied on π-π stacking. Based on this understanding, application of single-molecule-based versatile crystals in information encryption was demonstrated. It is believed that the evidence and unveiled mechanism for the effect of crystallization on emission will contribute to development in high-performance luminescent materials.

Structural Elucidation of Photoluminescent Carbon Nanodots through Quenching Kinetics with Molecular Electron Donors and Acceptors

Photoluminescence (PL) quenching mechanism and dynamics of carbon nanodots (CNDs) with molecular electron donors and acceptors are investigated by means of time-resolved emission spectroscopy. CNDs are prepared by direct pyrolysis from two different precursors, di-ammonium citrate and tri-ammonium citrate, at two different temperatures, 150 °C and 180 °C, for 40 hours under ambient conditions. Despite the small changes in the pyrolysis temperature, rather significant differences are observed in the structure, PL quantum yield, and hence observation of the important characteristics of PL quenching kinetics in the presence of benzophenone (BP) and dimethoxybenzene (DMB) as an electron acceptor and donor, respectively. Molecular dynamic simulations of CNDs in the presence of molecular quenchers support the spectroscopic data and the photophysical behavior of CNDs, and the distinct PL quenching dynamics are attributed to the hydrogen bonding interaction in the case of BP and the π π-stacking interaction in the case of DMB as PL quenchers.

Quadrupling the PLQY of Tetraphenylethylene by Covalently Linking it with Isosteric Tetraarylaminoborane: A Potential Candidate for Multicolor Live Cell Imaging

Applications of organic luminophores depend on their photoluminescence quantum yield (PLQY). Several strategies have been developed to improve the PLQY of organic solids, and one such method is aggregation-induced emission (AIE). Herein, we disclose a comprehensive study of two molecularly engineered covalently linked isosteric AIEgens, BNTPE-1 and BNTPE-2. The independent isosteres tetraarylaminoborane (BN) and tetraphenylethylene (TPE) showed poor PLQY; however, the covalently linked BNTPE-1 and BNTPE-2 systems showed 4 times higher PLQY than the independent isosteres (∼78 and ∼92% for solids and aggregates, respectively). Detailed optical, structural, and computational studies revealed that BN and TPE moieties adopt more coplanarity and have stronger donor (-NPh2)-acceptor (BMes2) interactions in the covalently linked systems than do simple BN and TPE units. Despite having sterically demanding BMes2 units, these compounds are nonemissive in the solution state due to the presence of flexible TPE units. However, they are strongly emissive in condensed states, such as aggregates in solution and the solid state. The excited state structure analysis revealed that the TPE unit undergoes severe conformational distortion after photoexcitation, which activates nonradiative decay channels and consequently quenches the luminescence in the molecularly dispersed state. The bioimaging potential of BNTPE-1 and BNTPE-2 was also explored. These compounds showed high biocompatibility and stained the HeLa cells brighter than BN and TPE molecules.

Phosphinylation/cyclization of propynolaldehydes to isobenzo-furanylic phosphine oxides displaying AIE properties

Investigating organic reactions to synthesize novel molecules that exhibit aggregation-induced emission (AIE) characteristics is becoming a research hotspot. Herein, we develop a one-pot phosphinylation/cyclization reaction between propynolaldehydes and diarylphosphine oxides to generate isobenzofuran-substituted phosphine oxides (IBFPOs) displaying AIE properties. Such a reaction possesses benefits such as metal-free synthesis, simple operation and wide substrate applicability. Further structural modifications of the products have been implemented through the palladium-catalyzed Sonogashira reaction, Ullmann coupling and Diels-Alder addition. Furthermore, these AIE luminogens (AIEgens), which have satisfactory quantum yields and tunable emission covering the entire visible region, can be employed for the cell imaging of lipid droplets in HeLa cells. Notably, quantitative evaluation of the phototherapy effect demonstrates that one of these presented AIEgens, namely IBFPO-3j, displays high type-I reactive oxygen species (ROS) generation efficiency, enabling its effective application in photodynamic therapy in a hypoxic environment.

Ligand-to-Ligand Charge Transfer Induced Red-Shifted Room Temperature Phosphorescence in Metal-Organic Frameworks

Research on room temperature phosphorescence (RTP) of metal-organic frameworks (MOFs) has been rapidly developed in recent years. However, it is still challenging to realize long-wavelength RTP (>580 nm). In this article, a new strategy is proposed to achieve the red-shifted RTP through constructing dual-ligand MOFs. Different from the single-ligand MOF, which lacks intermolecular interaction, the dual-ligand MOF can build up a stable donor-acceptor (D-A) relationship between two suitable simple ligands. Therefore, the induced charge transfer (CT) process from the donor units to the acceptor units in the framework can decrease the energy gap between the frontier orbitals, reducing the excited state energy levels. Moreover, by modulating the electron density and conjugation of the acceptor ligand, the energy of the triplet states of MOFs can be further reduced. As a result, the RTP centered at 588 nm is successfully achieved in a dual-ligand MOF. Also, we clearly describe the electron transporting path among the ground, 1CT, and 3CT states, revealing the emitting mechanism of the long-wavelength RTP. This work not only extends the D-A structure from the molecular level to the periodic structure of MOFs but also solves the problem of achieving long-wavelength RTP in MOFs from a new perspective.

Activatable peptide-AIEgen conjugates for cancer imaging

Aggregation-induced emission luminogens (AIEgens) have undergone significant development over the past decade, making substantial and profound contributions to a diverse range of research fields, prominently including cancer/disease diagnosis and therapy. Through the covalent conjugation of AIEgens with functional peptides, the resultant peptide-AIEgen conjugates possess not only the excellent biocompatibility characteristics, along with low systemic toxicity and negligible immunogenicity of peptides, but also the remarkable fluorescence properties of AIEgens. This "win-win" integration has significantly propelled the applications of peptide-AIEgen conjugates, particularly within the domain of cancer imaging. Three principal types of peptide-AIEgen conjugates, namely, tumor-targeting, tumor biomarker-responsive, and biomarker-responsive self-assembling peptide-AIEgen conjugates, are commonly devised. These conjugates confer enhanced targeting capabilities and selectivity towards tumors, thereby facilitating "smart" and precise tumor imaging with high signal-to-background ratios. In light of the crucial significance of peptide-AIEgen conjugates in tumor imaging and the recent inspiring breakthroughs that have not been encompassed in previous reviews, we present this review. We highlight the activatable peptide-AIEgen conjugates developed for tumor imaging over the past three years (from 2022 to the present). Particular attention is directed towards their design rationales, operational mechanisms, and imaging performance. Finally, prospective opportunities within this field are also reasonably deliberated.

Asymmetric D-A-D' Ratiometric Molecule for Highly Specific Hypochlorous Acid Detection

Hypochlorous acid exists as HClO in acidic conditions and as ClO- in alkaline conditions, posing a significant challenge for differentiation due to their strong and closely similar oxidative reaction activities. Addressing this challenge, our study presents an asymmetric donor-acceptor-donor' (D-A-D') molecular architecture for the design of a fluorescent probe (PMT NPs) that demonstrates exceptionally high specificity toward HClO alongside an optimized ratiometric response. The incorporation of the strong electron acceptor 2-(diphenylmethylene)malononitrile (A) modulates the reducing ability of the phenothiazine recognition site, adjusting the probe's oxidation potential to an intermediate level between HClO and ClO-. This adjustment directly dictates the probe's selectivity, enabling it to respond exclusively to HClO. By incorporating D', the probe's response to HClO shifts the intramolecular charge transfer (ICT) from the original D-A to D'-A, instead of the usual Dox-A as presented in previous works. This adjustment controls the blue shift in fluorescence wavelength upon recognition, thereby improving the accuracy of ratiometric signals in vivo. The ability of PMT NPs to precisely recognize HClO in acidic environments was validated through live cell imaging and in vivo experiments using zebrafish and mouse models, enabling real-time monitoring of HClO surges. This dual-pronged molecular design strategy, which combines D-A interaction modulation with a D-A-D' molecular architecture, promises to revolutionize probe designs for various biomolecules and is anticipated to advance the understanding of diseases linked to these analytes.

Afterglow Copper(I) Iodine Cluster Scintillator

Copper(I) iodine clusters have drawn intense attention due to their advantageous photophysical properties, such as a high luminescence efficiency, large Stokes shift, and tunable luminescence lifetimes. In this work, a copper(I) iodine cluster (Cu2I2-CH3CN) was synthesized, which exhibits unique afterglow emission, ultrahigh quantum yield (90.1 % in solid state) and aggregation-induced emission (AIE) behavior. It was found that thermally activated delayed fluorescence (TADF) and long-lifetime phosphorescence occur simultaneously in Cu2I2-CH3CN. The unique photoluminescence properties of Cu2I2-CH3CN were attributed to the large spin-orbit coupling (SOC) and long-term rigidity of the crystal. The high quantum efficiency, TADF characteristics, and heavy-atom composition of Cu2I2-CH3CN endow it with excellent X-ray excited luminescence (XEL) properties, making it a promising X-ray scintillator. A flexible scintillator screen made of Cu2I2-CH3CN was successfully fabricated and used for X-ray imaging with a spatial resolution of 23.6 LP mm-1.

Anion-π interaction guided switchable TADF and low-temperature phosphorescence in phosphonium salts for multiplexed anti-counterfeiting

Anion-π+ interactions have gained continuous attention in diverse organic aggregates, as they can effectively alter emission behavior. Herein, the anion-π+ interaction is introduced to phosphonium salts, which exhibit tunable thermally activated delayed fluorescence and phosphorescence emission. Intriguingly, the emission spectra evolve from deep-blue to yellow emission by regulation of the anion-π+ interaction strength through varying the anions, such as BF4 -, CF3SO3 -, PF6 -, and NO3, accompanied by adjustable luminescent decay times from milliseconds to several seconds. Notably, bright blue emission with a high photoluminescence quantum yield near 100% is achieved when substituting the iodide ions with larger counter anions. The phosphonium iodide with strong anion-π+ interaction and heavy atom effect shows a high inter-system crossing rate, which inhibits the direct and prompt fluorescence emission. The anion-π+ interaction and twisted structure strongly suppress π-π stacking and afford ultra-high photoluminescence yields. Furthermore, the participation of polar solvent molecules results in the solvation and bathochromic-shift phenomenon of the solid-state phosphonium iodide due to the ionic polarized host-guest structure. This work provides new insights into the anion-π+ interaction in luminescent phosphonium aggregates.

Design strategies for tetrazine fluorogenic probes for bioorthogonal imaging

Tetrazine fluorogenic probes play a critical role in bioorthogonal chemistry, selectively activating fluorescence upon reaction to enhance precision in imaging and sensing within complex biological environments. Recent structural innovations-such as varied fluorophore choices, spacer optimization, and direct tetrazine integration within a fluorophore's π-conjugated system-have expanded their spectral range from visible to NIR, enhancing adaptability across various applications. This review examines advancements in the rational design and synthesis of these probes. We examine key fluorogenic mechanisms, such as energy transfer, internal conversion, and electron/charge transfer, that significantly influence fluorescence activation. We also highlight representative applications in live-cell imaging, super-resolution microscopy, and therapeutic monitoring, underscoring the expanding role of tetrazine probes in biomedical research and diagnostics. Collectively, these insights provide a strategic foundation for developing next-generation tetrazine probes with tailored properties to address evolving diagnostic and therapeutic challenges.

Anthracene appended AIEgen as a reversible fluorescence sensor for hazardous cyanide ion in environmental samples and fabrication of portable test kit for on spot detection

CN- is a frequently encountered pollutant in water and soil. Due to its extreme lethal effect on mammals, serious consideration and efforts are needed for monitoring this hazardous anion. To address this challenge, herein, an anthracene-appended AIEgen (ACFH) has been synthesized and developed for selective fluorometric detection of CN- ion. The detection limit of the probe has been found to be 3.42 × 10-7 M (8.89 ppb), which is much lower than WHO standard (2.7 × 10-6 M). The interaction with CN- causes deprotonation of the probe and subsequent loss of planarity, which has been thoroughly confirmed from 1H NMR titrations and DFT calculations. The reversibility and reusability of ACFH and corresponding logic gates enhance its sensing performance and efficacy. Notably, it has been utilized to meritoriously quantify CN- in various water samples and the fabrication of a portable test kit for monitoring CN- in real time. In addition, the aggregation induced emission (AIE) property has been precisely explored with the aid of fluorescence spectroscopy, dynamic light scattering (DLS), scanning electron microscopy (SEM), fluorescence quantum yield and lifetime analysis.

Flexible Formation of Nanoparticles: Selectively Self-Assembling with Glycoclusters to Form Nano-Photosensitizers for Multipurpose Bioimaging and Photodynamic Therapy

The smart construction of nano-photosensitizers (PSs) is significant for multipurpose applications, such as bioimaging, efficient photodynamic anti-tumor or anti-bacterial studies. This work reports a flexible self-assembling strategy for the construction of nano-PSs, in which PSs spontaneously form amorphous aggregates for killing bacteria, or self-assemble with tetraphenylethene (TPE) based glycoclusters (TPE-Glc4) to construct glyco-dots for cell imaging and photodynamic anti-tumor studies. Tricyanofuran (TCF) and TPE units were bridged with furan or thiophene moiety to construct two PSs (1 and 2) with NIR fluorescence in monomers, and a performance of the aggregation-induced generation of reactive oxygen species (AIG-ROS) in an aggregated state. Compared to the large amorphous aggregates (2-a), TPE-based glycoclusters encapsulated with PS form glyco-dots (2-Glc) that exhibit a smaller and more homogeneous hydrated size of approximately 40 nm, as well as enhanced water-solubility and biocompatibility. TPE-glycoclusters facilitate the cellular uptake of 2 into HepG2 cells, therefore enhancing the NIR fluorescence imaging signal and photodynamic therapy. Meanwhile, 2-a exhibits satisfied phototoxicity against Escherichia coli. This work highlights the flexible self-assembly of nano-PSs for multifunctional bioapplications.

AIE Bottlebrush Polymers: Verification of Internal Crowdedness in Bottlebrush Polymers Using the AIE Effect

Bottlebrush polymers, characterized by densely grafted side chains along a central backbone, have gained significant interest due to their unique properties in bulk and solution states. Despite extensive research, a comprehensive understanding of the internal crowdedness within single polymer chains in dilute solutions remains challenging, and direct evidence to visualize and manifest this effect is scarce. Aggregation-induced emission (AIE) offers a novel method to address this challenge. To achieve this, a vinyl-derivatized AIE monomer was polymerized using atom transfer radical polymerization (ATRP) in a controlled way. Afterward, the end group of the synthesized polymer chain was transformed to azide, which was coupled with an alkyne-derivatized norbornene unit using click chemistry to produce the macromonomer. Ring-opening metathesis polymerization (ROMP) of the norbornenyl macromonomer using Grubbs catalyst, (H2IMes)(pyr)2(Cl)2Ru = CHPh (G3), resulted in well-defined bottlebrush polymers in a highly efficient way. We studied the polymerization behavior and characterized the single chain conformation of the bottlebrush polymers in dilute solution together with coarse-grained molecular dynamics (CG-MD) simulation. Photoluminescence investigation of the bottlebrush polymers in dilute solution revealed the expected AIE phenomenon, thus verifying the steric crowding effects within bottlebrush polymers. This work bridges AIE technology with polymer science and especially bottlebrush polymers. By doing this, our research not only broadens the bottlebrush polymer library but also provides insights into bottlebrush polymer chain study for potential applications.

Structures and Properties of Axially Chiral (2E,4E,6Z,8Z)-Nona-2,4,6,8-Tetraenoate Derivatives Highly Substituted by Aryl Groups

Unprecedented (2E,4E,6Z,8Z)-nona-2,4,6,8-tetraenoate derivatives highly substituted by aryl groups have been synthesized by the reaction of rhodium complexes having aryl-substituted hexa-1,3,5-trienyl ligands with acrylates. These compounds have potential axial chirality, and their enantiomers are isolable by the chiral HPLC technique. Although the racemization barrier of isolated enantiomers was not high, it was found that a cyclic dimer synthesized by head-to-tail transesterification of a modified analog has quite a stable axial chirality even at a high temperature. From a structural analogy with tetraphenylethene, those compounds are emissive in the solid state, and the chiral cyclic dimer exhibits solid-state circularly polarized luminescence (CPL) activity.

A Brain-Targeting NIR-II Polymeric Phototheranostic Nanoplatform toward Orthotopic Drug-Resistant Glioblastoma

Glioblastoma is the most common and devastating brain tumor owing to its high invasiveness and high-frequency drug resistance. Near infrared-II (NIR-II) imaging-guided phototherapy based on polymer luminogens provides a promising remedy against drug-resistant glioma, but it is difficult to maximize photoenergy utilization. Herein, we designed a series of semiconducting polymers to boost the visualization and ablation of glioblastoma. By subtly engineering the side chains or substituents on the phenothiazine and thiophene moieties, an NIR-II polymer luminogen with high-quality fluorescence performance, good solubility, superior photothermal conversion, and balanced reactive oxygen species generation is achieved. The optimal polymer possesses a branched alkyl chain and tetraphenylethylene pendant to manipulate the equilibrium between the radiative and nonradiative energy-dissipating channels. High-sensitivity NIR-II imaging was used to monitor the blood-brain barrier penetration and glioma cell targeting of apolipoprotein E-modified polymer nanoparticles. The NIR irradiation triggers and maximizes the photon utilization in prominent photodynamic/photothermal synergistic therapy in orthotopic drug-resistant glioblastoma.

Aggregation-Induced Emission in Bridged (E,E)-1,4-Diphenyl-1,3-butadiene Derivatives with Six- and Seven-Membered Rings

Recently, we developed a new aggregation-induced emission (AIE) luminogen (AIEgen), bridged stilbene, by incorporating a propylene group into the C=C bond of the luminescent phenyl stilbene. This bridged structure, featuring a seven-membered ring, induces a significant conformational change, causing the C=C bond to twist in the excited state, thereby enhancing non-radiative decay in solution. In this study, we introduced bridged structures with alkylene groups of varying lengths into (E,E)-1,4-diphenyl-1,3-butadiene (DPB). The variation in the bridged structures of the synthesized DPB derivatives notably influenced the environmental sensitivity of fluorescence. Whereas the compound with two six-membered ring structures exhibited emission in solution and in the polycrystalline state, derivatives with a seven-membered ring exhibited AIE properties. Specifically, BDPB[7,7], featuring two seven-membered ring structures, demonstrated AIE characteristics with solid-state luminescence originating from J-aggregates. However, the fluorescence quantum yield was low in poly(methyl methacrylate) (PMMA) dispersion films, where molecular motion was restricted. These findings open new possibilities for designing unique AIEgens that remain nonluminescent even in highly viscous or confined environments, such as PMMA films.

Acceptor Elongation Boosted Intersystem Crossing Affords Efficient NIR Type-I and AIE-Active Photosensitizers for Targeting Ferroptosis-Based Cancer Therapy

Photosensitizers (PSs) featuring type I reactive oxygen species (ROS) generation and aggregation-induced emission (AIE) activity offer a promising solution to achieve non-invasive and precise theranostics. However, the reported AIE luminogens (AIEgens) with both AIE characteristic and strong type-I ROS generation are still scarce and the structure-property relationship is still unclear. Herein, an innovative acceptor elongation boosted intersystem crossing (AEBIC) design strategy has been proposed to endow the AIEgen strong type-I ROS producibility. The results indicate that the obtained AIEgen exhibit type-I ROS and aggregation-enhanced ROS efficacy, which has been verified by both experimental and theoretical results. Mechanistic study reveal that the acceptor elongation has promoted a dual-channel intersystem crossing pathway to enhance the intersystem crossing (ISC) process due to the differences in triplet configurations, which can be further amplified by aggregation. The afforded type-I AIE-PS show lipid droplet-anchored characteristic and can induce the ferroptosis through destroying the cellular redox homeostasis and increasing lethal levels of lipid peroxidation. Finally, targeting ferroptosis-based cancer therapy can be realized with excellent anti-tumor effect.

Pressure-Modulated Luminescence Enhancement and Quenching in a Hydrogen-Bonded Organic Framework

Light emission in the solid state is central for illumination, sensing, and imaging applications. Unlike luminescence in dilute solutions, where the excited states are unimolecular in nature, intermolecular interaction plays a significant role in the quantum yield of solid-state luminophores, manifested as competing aggregation-caused quenching (ACQ) and aggregation-induced enhancement (AIE). Both effects are extensively studied in various systems; however, it remains unclear how their competition depends on molecular conformation and intermolecular stacking. Here the direct observation of pressure-modulated AIE-ACQ competition in a crystalline hydrogen-bonded organic framework (HOF) is reported. Using in situ spectroscopies and computational modeling, the intramolecular vibration and intermolecular π-π stacking directly responsible for the non-radiative decay of the excited state are identified. The extent of these two contributions is modulated by hydrostatic pressure and guest molecules in the HOF pores. This work demonstrates a physically neat model system to understand and control solid-state luminescence, and a potential material platform for piezoluminescent sensing.

Tetra-coordinated organoboron complexes with triaminoguanidine-salicylidene based ligands: aggregation induced enhanced emission and mechanoresponsive features

Organoboron complexes have garnered significant attention due to their remarkable optical properties and diverse applications. However, synthesizing stable fused five-, six- and seven-membered organoboron complexes possess significant challenges. In this study, we successfully developed novel mono-nuclear (6-8 & 10) and di-nuclear (9) organoboron complexes supported by triaminoguanidine-salicylidene based C3-symmetric Schiff base ligands via one-step condensation reaction with excess phenylboronic acid. Single-crystal X-ray diffraction analysis revealed that in the mononuclear complexes (6-8 & 10), boron atoms adopt tetrahedral geometry with fused five-membered N-B-N and six-membered O-B-N chelate ring whereas in the dinuclear complex (9), two boron atoms exist in distinct coordination environment, forming four fused boron-incorporated rings, including six-membered N-B-N, six-membered O-B-N, seven-membered N-B-O and five-membered N-B-N chelate rings. Our findings provide a unique family of mononuclear organoboron complexes and dinuclear organoboron complex with ESIPT unit. Aggregation induced enhanced emission features of the compounds were established in THF-water mixture and supported by DLS and SEM analyses. Interestingly, compound 6, 9 and 10 shows interesting mechanoresponsive features upon grinding.

Advances in aggregation-induced emission luminogens for biomedicine: From luminescence mechanisms to diagnostic applications

Advancements in early detection have demonstrated the significance of biomarkers as indicators of health and disease. Traditional detection methods often face limitations, such as low sensitivity and time consumption. Fluorescence-based techniques are considered promising approaches because of their noninvasiveness and rapid response. However, these conventional methods have some drawbacks, such as low quantum yield, photobleaching, and aggregation-caused quenching. Recently, aggregation-induced emission (AIE) has emerged as a potential alternative, characterized by luminous emission upon aggregation, thus improving detection sensitivity and stability. This review explores the recent advancements in AIE luminogens (AIEgens) in biomedical engineering, with a particular focus on their application in biomarker detection. Here, we discuss the different types of AIE mechanisms and their advantages in disease diagnosis and imaging. In addition, we summarize the development of various AIEgen-based probes for the detection of diverse biomarkers. Finally, we address the remaining challenges and future directions for AIE materials in modern biomedical engineering, emphasizing the potential of AIEgens in biomarker detection and disease diagnosis strategies.

Antagonistic Effects of Distance and Overlap toward Anomalous Pressure-Induced Blueshift of π-π Excimer Fluorescence in 9-(2,2-Diphenylvinyl)anthracene Crystals

Piezochromic materials usually exhibit a gradual redshift of emission as pressure increases due to the formation of a low-energy "dark" state, e.g., excimer. However, our study presents an anomalous excimer-based pressure-induced emission blueshift. A crystal was investigated here with a discrete π-π anthracene dimer stacking and excimer emission, and the dimer is characterized by an overshifted off-center stacking pattern. Intriguingly, under isotropic hydrostatic pressure, this crystal exhibits negative linear compressibility almost along the c-axis of the unit cell. Furthermore, an antagonistic effect between overlap ratio (Sπ-π) and interplanar distance (Dπ-π) within the dimer on emission was identified: reduced Dπ-π typically dominates the emission redshift, while decreasing Sπ-π can cause emission blueshift. When the pressure reaches around 5.00 GPa, the π-π excimer fluorescence exhibits an unexpected blueshift, indicating the reign of decreasing Sπ-π. This study not only sheds light on the modulation of fluorescence properties by noncovalent interactions but also introduces an innovative approach to anomalous piezochromism.

Synthesis and Optoelectronic Properties of Perylene Diimide-Based Liquid Crystals

Perylene diimide (PDI), initially synthesized and explored as an organic dye, has since gained significant recognition for its outstanding optical and electronic properties. Early research primarily focused on its vibrant coloration; however, the resolution of solubility challenges has revealed its broader potential. PDIs exhibit exceptional optical characteristics, including strong absorption and high fluorescence quantum yield, along with remarkable electronic properties, such as high electron affinity and superior charge carrier mobility. Furthermore, the robust π-π stacking interactions and liquid crystalline behavior of PDIs facilitate precise their self-assembly into highly ordered structures, positioning them as valuable materials for advanced applications in optoelectronics, photonics, and nanotechnology. This article provides a comprehensive review of the progress made in the design, synthesis, and optoelectronic performance of PDI-based liquid crystals. It explores how various substituents and their placement on the PDI core impact the properties of these liquid crystal molecules and discusses the challenges and opportunities that shape this rapidly evolving class of optical materials. This review is strictly focused on PDIs and does not cover their elongated or laterally extended derivatives, nor does it include monoimide or ester compounds.

Hydrazone fluorescent sensors for the monitoring of toxic metals involved in human health from 2014-2024

Hydrazone-based fluorescent sensors have been instrumental for the detection of toxic metals over the past decade due to their ease of synthesis and unique properties. This review summaries the diverse range of sensors reported for toxic metals (Al3+, Fe3+, Cu2+, Zn2+ and Hg2+) highlighting the key role this class of sensors will play in the foreseeable future.

Chitosan as a fluorescent probe for the detection of the AIE-active food colorant quinoline yellow

The greenish-yellow synthetic dye quinoline yellow (Qy) is widely used in the food and pharmaceutical industries. However, this dye may lead to health and environmental problems. Therefore, investigating how Qy interacts with biological macromolecules is of great interest. In this work, Qy was found to be a novel AIEgen having strong solid-state emission and water-solubility. Adding tetrahydrofuran to an aqueous solution of Qy induced Qy to form nanoaggregates, which increased its fluorescence intensity. Moreover, we found that Qy was able to interact with typical biological macromolecules, such as chitosan, BSA, and DNA, and quench these biomolecules' intrinsic fluorescence. Therefore, chitosan was chosen as a probe for Qy detection. The results showed that chitosan could detect Qy in the presence of interfering ions, other dyes, and sucrose, as well as in an acidic environment. Finally, chitosan was used to determine the quantity of Qy in orange juice and wine. This is the first report of the identification of a food colorant as an AIEgen, and this AIE activity has been wisely harnessed to visualize molecular interactions between Qy and biological macromolecules, as well as to detect Qy in beverages.

PLGA confers upon conventional nonfluorescent molecules luminescent properties to trigger 1O2-induced pyroptosis and immune response in tumors

Pyroptosis, a recently identified cellular demise regulated by gasdermin family proteins, is emerging as a promising avenue in cancer immunotherapy. However, the realm of light-controlled pyroptosis in cancer cells remains largely unexplored. In this study, we took a deliberate approach devoid of any chemical alterations to develop a novel photosensitizer called "pharmaceutical-dots (pharm-dots)" by combining nonemissive polymers (Poly (lactic-co-glycolic acid), PLGA) with nonfluorescent invisible molecules like curcumin, berberine, oridonin into PLGA nanoparticles (PLGA-NPs). Initially, our research commenced with a comprehensive mechanistic comparison study, consolidating fragmented information on optical mechanisms. This exploration revealed that surface passivation atoms play a dominant role in governing the fluorescence emission of PLGA-NPs. Remarkably, these new luminophores, composed of two non-inherently luminous components, exhibit a remarkable synergistic boost in photoluminescence through a "0 + 0 > 2" phenomenon. In-depth investigations uncovered that these luminous PLGA-NPs, capable of generating 1O2, induce pyroptosis under photoexcitation conditions through the caspase-3/gasdermin E (GSDME) pathway. Simultaneously, our findings highlight PLGA-NPs as a novel optical formulation suitable for imaging, displaying substantial biological activity when paired with photoirradiation. This discovery holds the potential to facilitate the application of light-controlled pyroptosis in antitumor therapy, marking a promising stride toward innovative approaches in cancer treatment.

Supramolecular Reconstruction of Self-Assembling Photosensitizers for Enhanced Photocatalytic Hydrogen Evolution

Natural photosynthetic systems require spatiotemporal organization to optimize photosensitized reactions and maintain overall efficiency, involving the hierarchical self-assembly of photosynthetic components and their stabilization through synergistic interactions. However, replicating this level of organization is challenging due to the difficulty in efficiently communicating supramolecular nano-assemblies with nanoparticles or biological architectures, owing to their dynamic instability. Herein, we demonstrate that the supramolecular reconstruction of self-assembled amphiphilic rhodamine B nanospheres (RN) through treatment with metal-phenolic coordination complexes results in the formation of a stable hybrid structure. This reconstructed structure enhances electron transfer efficiency, leading to improved photocatalytic performance. Due to the photoluminescence quenching property of RN and its electronic synergy with tannic acid (T) and zirconium (Z), the supramolecular complexes of hybrid nanospheres (RNTxZy) with Pt nanoparticles or a biological workhorse, Shewanella oneidensis MR-1, showed marked improvement in photocatalytic hydrogen production. The supramolecular hybrid particles with a metal-phenolic coordination layer showed 5.6- and 4.0-fold increases, respectively, in the productivities of hydrogen evolution catalyzed by Pt (Pt/RNTxZy) and MR-1 (M/RNTxZy), respectively. These results highlight the potential for further advancements in the structural and photochemical control of supramolecular nanomaterials for energy harvesting and bio-hybrid systems.

Biodegradable Nanobowls with Controlled Dents

Nanobowls show promising potential in biomedical applications, such as bioimaging, cargo delivery, and disease theranostics, due to their unique concave structure and interior cavities. However, the lack of biodegradable nanobowls with manipulable size (especially the dent size) still exists as an obstacle for their in-depth exploration and application in biomedical fields. Herein, polypeptide-based nanobowls are successfully obtained by the self-assembly of a graft polypeptide [named TPE-P(GAAzo21-stat-GA29)] via a solvent-switch method. Through the synergistic effect between the hydrogen bonding and π-π stacking interactions, the size of nanobowls and the corresponding dents can be facilely controlled by altering either the initial polypeptide concentration or the cosolvents in self-assembly. Furthermore, such polypeptide-based nanobowls are demonstrated to be biocompatible and biodegradable in vitro, which may promote the development of biomedical nanobowls in the future.

Luminescent Radical Polymers

Organic radicals are gaining significant interest in luminescent materials due to their unique properties, which present unprecedented opportunities for innovation across various fields, from display technology to biomedical applications. However, addressing challenges related to stability and low fluorescence efficiency is crucial to unlocking their full potential for practical applications. Polymerization has emerged as an effective strategy to enhance intra- and interchain through-space interactions, enabling the creation of stable luminescent radicals with excellent processing and multifunctional properties. This concept emphasizes the strategic use of polymerization in designing and synthesizing stable main-chain and side-chain radical polymers. This approach not only broadens the scope of stable radicals but also improves their luminescence properties as photofunctional materials.

Rotor proliferation promotes high-brightness AIE of iridium emitter accomplishing high-contrast luminous imaging of latent fingerprints to level 3 details

Luminous imaging of latent fingerprints (LFPs) necessitates the possession of high-brightness aggregation-state luminescence by developers to ensure sufficient imaging contrast and resolution. A novel strategy involving incremental rotor modification is presented for AIE activation of the iridium developer. The rotor proliferation prominently improves the rotational activity of groups and facilitates high-efficiency RIM, thereby prompting the AIE activation of iridium developer with high luminous efficiency. Subsequently, a prompt, high-contrast, and robust LFP imaging protocol is developed utilizing the high-brightness AIE-active iridium developer. This innovative protocol realizes the luminous imaging and quantification of microscopic features in fingerprint ridges and furrows, including ridge widths, edge morphology of ridges, included angles, pores, and pore pitches with exceptional imaging contrast and refined detail resolution. Moreover, it allows for accurate identification of individual traits across diverse substrates without any pre-/post-processing to LFPs. The high-brightness AIE-active iridium developer provides outstanding aging resistance to developed fingerprints, thereby strongly supporting the acquisition, transfer, and preservation of fingerprint evidence. The luminous imaging protocol of LFPs based on high-brightness AIE exhibits robust adaptability to actual scenes and offers a premium scheme for facilitating forensic investigation.

Tetraphenylethylene-Derived Tetracarboxylate Featuring AIE Properties for Dual Ion Sensing and Mechanochromic Self-Erasable Writing

The integration of multiple functions within a single fluorescent molecule provides a promising platform for developing versatile, efficient, and cost-effective materials with enhanced performance across diverse applications. In this study, we introduce TPEC, an aggregation-induced emission (AIE) molecule derived from tetraphenylethylene-based tetracarboxylate, which demonstrates multifunctional capabilities, including metal ion sensing and self-erasable writing. TPEC exhibits amphiphilicity in water, self-assembling into single-layer nanosheets with robust blue fluorescence. Notably, the aqueous solution of TPEC displays a fluorescence colorimetric response to Al3+ ions and fluorescence quenching in the presence of Fe3+ ions. Additionally, TPEC powders undergo fluorescence colorimetric changes under mechanical stimulation, enabling self-erasable writing on prepared paper. This study presents a straightforward strategy for the development of multifunctional luminescent materials based on the self-assembly of a single-component fluorophore.

Aggregation-Induced Emission Luminogens Realizing High-Contrast Bioimaging

A revolutionary transformation in biomedical imaging is unfolding with the advent of aggregation-induced emission luminogens (AIEgens). These cutting-edge molecules not only overcome the limitations of traditional fluorescent probes but also improve the boundaries of high-contrast imaging. Unlike conventional fluorophores suffering from aggregation-caused quenching, AIEgens exhibit enhanced luminescence when aggregated, enabling superior imaging performance. This review delves into the molecular mechanisms of aggregation-induced emission (AIE), demonstrating how strategic molecular design unlocks exceptional luminescence and superior imaging contrast, which is crucial for distinguishing healthy and diseased tissues. This review also highlights key applications of AIEgens, such as time-resolved imaging, second near-infrared window (NIR-II), and the advancement of AIEgens in sensitivity to physical and biochemical cue-responsive imaging. The development of AIE technology promises to transform healthcare from early disease detection to targeted therapies, potentially reshaping personalized medicine. This paradigm shift in biophotonics offers efficient tools to decode the complexities of biological systems at the molecular level, bringing us closer to a future where the invisible becomes visible and the incurable becomes treatable.

Neuronal Tracing and Visualization of Nerve Injury by a Membrane-Anchoring Aggregation-Induced Emission Probe

Deciphering neuronal circuits is pivotal for deepening our understanding of neuronal functions and advancing treatments for neurological disorders. Conventional neuronal tracers suffer from restrictions such as limited penetration depth, high immunogenicity, and inadequacy for long-term and in vivo imaging. In this context, we introduce an aggregation-induced emission luminogen (AIEgen), MeOTFVP, engineered for enhanced neuronal tracing and imaging. MeOTFVP is strategically designed to target cell membranes by integrating into the phospholipid bilayer through its amphipathy. The donor-acceptor molecular skeleton facilitates a red shift of its photoluminescence into the near-infrared (NIR) spectrum, significantly improving tissue penetration. The affinity of MeOTFVP for cell membranes, coupled with its deep tissue penetration, allows precise tracing in the paw-dorsal root ganglia (DRG) circuit and detailed imaging of the sciatic nerve. This study showcases the application of MeOTFVP as a dual-function neuronal tracer, propelling forward the possibilities for advanced neuronal tracing and imaging using AIEgens.

Self-Assembled Nanohelixes Driven by Host-Guest Interactions and Metal Coordination

Helical nanostructures fabricated via the self-assembly of artificial motifs have been a captivating subject because of their structural aesthetics and multiple functionalities. Herein, we report the facile construction of a self-assembled nanohelix (NH) by leveraging an achiral aggregation-induced emission (AIE) luminogen (G) and pillar[5]arene (H), driven by host-guest interactions and metal coordination. Inspired by the "sergeants and soldiers" effect and "majority rule" principle, the host-guest complexation between G and H is employed to fixate the twisted conformation of G for the generation of "contortion sites", which further induced the emergence of helicity as the 1D assemblies are formed via Ag(I) coordination and hexagonally packed into nano-sized fibers. The strategy has proved feasible in both homogeneous and heterogeneous syntheses. Along with the formation of NH, boosted luminescence and enhanced productivity of reactive oxygen species (ROS) are afforded because of the efficient restriction on G, indicating the concurrent regulation of NH's morphology and photophysical properties by supramolecular assembly. In addition, NH also exhibits the capacity for bacteria imaging and photodynamic antibacterial activities against Staphylococcus aureus (S. aureus) and Escherichia coli (E. coli).

Bioorthogonally activated probes for precise fluorescence imaging

Over the past two decades, bioorthogonal chemistry has undergone a remarkable development, challenging traditional assumptions in biology and medicine. Recent advancements in the design of probes tailored for bioorthogonal applications have met the increasing demand for precise imaging, facilitating the exploration of complex biological systems. These state-of-the-art probes enable highly sensitive, low background, in situ imaging of biological species and events within live organisms, achieving resolutions comparable to the size of the biomolecule under investigation. This review provides a comprehensive examination of various categories of bioorthogonally activated in situ fluorescent labels. It highlights the intricate design and benefits of bioorthogonal chemistry for precise in situ imaging, while also discussing future prospects in this rapidly evolving field.