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The importance of halogen bonds (XBs) in the regulation of material properties through a variation in the electrostatic potential of the halogen atom is not attracted much attention. Herein, this study utilizes in situ single crystal X-ray diffraction and synchrotron-based X-ray techniques to investigate the cooling-triggered irreversible single-crystal-to-single-crystal transformation of the DMF solvated iodo-substituted squaraine dye (SQD-I). Transformation is observed to be mediated by solvent-involved XB formation and strengthening of electrostatic interaction between adjacent SQD-I molecules. By immersing a DMF solvate in acetonitrile a solvent exchange without loss of long-range ordering is observed. This is attributed to conservation of the molecular charge distribution of SQD-I molecules during the process. The different solvates can be used in combination for temperature-dependent image encryption. This work emphasizes the changes caused by XB formation to the electrostatic potentials of halogen containing molecules and their influence on material properties and presents the potential utility of XBs in the design of soft-porous crystals and luminescent materials.

Trace NO2 detection is essential for the production and life, where the sensing strategy is appropriate for rapid detection but lacks molecular specificity. This investigation proposes a sensing mechanism dominated by surface-scattering to achieve the molecularly-specific detection. Two-dimensional Bi2O2Se is firstly fabricated into a Schottky-junction-based gas-sensor. Applied with an alternating excitation, the sensor simultaneously outputs multiple response signals (i.e., resistance, reactance, and the impedance angle). Their response times are shorter than 200 s at room temperature. In NO2 sensing, these responses present the detection limit in ppt range and the sensitivity is up to 16.8 %·ppb−1. This NO2 sensitivity presents orders of magnitude higher than those of the common gases within the exhaled breath. The impedance angle is involved in the principle component analysis together with the other two sensing signals. Twelve kinds of typical gases containing NO2 are acquired with molecular characteristics. The change in dipole moment of the target molecule adsorbed is demonstrated to correlate with the impedance angle via surface scattering. The proposed mechanism is confirmed to output ultra-sensitive sensing responses with the molecular characteristic.

Photosensitizers (PSs) with effective reactive oxygen species generation ability against hypoxia are of great potential for clinical treatment of malignant tumors. However, complex tumor microenvironment, such as antioxidative responses and immunosuppression, would ineluctably limit the efficiency of photodynamic therapy (PDT). Herein, a molecular-targeting photosensitizer QTANHOH is rationally designed for histone deacetylases (HDACs-targeting photo-immunotherapy application. The PS QTANHOH displays excellent type-I/II PDT performance, exhibiting significant phototoxicity toward cancer cells with half maximal inhibitory concentration (IC50) less than 10 nm in both normoxia and hypoxia conditions under blue laser irradiation. Moreover, the bioactive compound could inhibit HDACs and activate the immune microenvironment to boost PDT efficacy on the immunocompetent BALB/c mice with breast cancer, leading to the eradication of solid tumor and inhibition of metastasis. Notably, the molecular-targeting photosensitizer introduces an alternative strategy to achieve superior phototherapy for cancer therapy.

Nonalcoholic steatohepatitis (NASH) is the critical stage in the development of nonalcoholic fatty liver disease (NAFLD) from simple and reversible steatosis to irreversible cirrhosis and even hepatocellular carcinoma (HCC). Thus, the diagnosis of NASH is important for preventing the progress of NAFLD into a fatal condition. The oxidative enzyme myeloperoxidase (MPO), which is mostly produced by polymorphonuclear neutrophil granulocytes (NEU), has been identified as a key player in lipid peroxidation in inflamed tissues. Considering that the expression of MPO was much higher in NASH than in the nonalcoholic fatty liver (NAFL) with steatosis, we designed a nanoparticle platform based on ultrasmall iron oxide (USIO) nanoparticles to realize MPO-sensitive NASH diagnosis. After modification of USIO nanoparticles with amphiphilic poly(ethylene glycol) (PEG) and conjugation with 5-hydroxytryptamine (5HT), a physiological substrate for MPO, the final nanocomposite (USIO-DA-PEG-5HT) revealed MPO-mediated aggregation at the inflammatory site of NASH. Meanwhile, the intrinsic T1-weighted magnetic resonance (MR) signal of dispersed USIO-DA-PEG-5HT nanoparticles diminishes, while the T2-weighted MR signal is amplified owing to the aggregation effect. These USIO-DA-PEG-5HT nanoprobes offer great potential for improving NASH MR imaging diagnostic accuracy and sensitivity compared to existing molecular MR contrast agents with a single imaging modality.

Photodynamic therapy (PDT) is a minimally invasive therapeutic modality. However, the residual photosensitizers (PSs) after PDT can still produce toxic singlet oxygen (1O2) under sunlight to damage normal tissues. The PS that can be switched off after PDT is desirable but rare. Herein, we propose a general strategy to design effective and self-degradable PSs by embedding an anthracene bridge into donor–acceptor (D–A) structures. First, the steric anthracene can regulate the orbital distribution for enhancing the 1O2 production capacity. More importantly, the anthracene is responsive to the self-produced 1O2 for self-degradation. Besides, the degradation rate can be fine-tuned by the hydrophilicity of PSs. In this way, the PSs can realize a balance between treatment and suicide to ensure PDT and post-treatment safety. This work provides new insights into the design of degradable PSs with a clear mechanism, aiming to improve the post-safety of PDT.

Developing a ferroelectric tunnel junction with a robust polarization reversal is essential for errorless data storage, but it remains challenging since the second-order phase transition dominates the reversal and introduces intermediate states. This investigation has proposed a charge-gradient-induced ferroelectricity, which is featured with the first-order phase transition. As an order parameter, a charge-gradient-induced polarization is achieved by modulation of stoichiometric oxygen along the Bi2O2Se/Bi2Se3O9 bilayer during pulsed laser deposition. At room temperature, this polarity points out-of-plane and shows an abrupt reversal in the ferroelectric hysteresis loop. The coercive field only increases by 0.04 V/nm after 300 reversals. Fabricated into the ferroelectric tunnel junction, the bilayer ferroelectric exhibits a comparable electroresistance of 100. The ON/OFF state can be switched repeatedly or after a 360 s retention. Characterizations of scanning capacitance microscopy and the current–voltage relation demonstrate that the ON/OFF switching is based on an injection exchange between the tunnelling and the thermionic emission.

π-Molecules play important roles in many applications such as organic light-emitting devices, photocatalysis, photovoltaics, biosensors, and medicine. Very often, π-conjugated molecules with high utilization of excited states in the solid state are of great research interest. However, owing to the gap between molecular structure and effective molecular packing, there are very few designs toward π molecules with very high exciton utilization in the solid state. Herein, we report a new π skeleton, folded π, to achieve high exciton utilization in the solid state. Based on a “folded π” formula, 12 compounds with two or three folding π planes were designed and synthesized. We found that folded π molecules tend to form well-aligned 1D molecular columns of patterns (“box”, “braid”, or “stair”) with high packing energy, which is mainly contributed by numerous weak π interactions. As a result of effective suppression of molecular motion, all the compounds show very high exciton utilization in solids.

Three conjugated polymers that have the same donor–acceptor structure but totally different architectures are designed to show both Type-I and Type-II photosensitization abilities simultaneously, among which the hyperbranched polymer shows the best performance in both in vitro and in vivo experiments, superior to even the commonly used clinical photosensitizer of hemoporfin.

The pursuing of photosensitizers (PSs) with efficient reactive oxygen species (ROS) especially type I ROS generation in aggregate is always in high demand for photodynamic therapy (PDT) and photoimmunotherapy but remains to be a big challenge. Herein, we report a cationization molecular engineering strategy to boost both singlet oxygen and radical generation for PDT. Cationization could convert the neutral donor-acceptor (D-A) typed molecules with the dicyanoisophorone-triphenylamine core (DTPAN, DTPAPy) to their A-D-A′ typed cationic counterparts (DTPANPF6 and DTPAPyPF6). Our experiment and simulation results reveal that such cationization could enhance the aggregation-induced emission (AIE) feature, promote the intersystem crossing (ISC) processes, and increase the charge transfer and separation ability, all of which work collaboratively to promote the efficient generation of ROS especially hydroxyl and superoxide radicals in aggregates. Moreover, these cationic AIE PSs also possess specific cancer cell mitochondrial targeting capability, which could further promote the PDT efficacy both in vitro and in vivo. Therefore, we expect this delicate molecular design represents an attractive paradigm to guide the design of type I AIE PSs for the further development of PDT.

Porous organic cages (POCs) have many advantages, including superior microenvironments, good monodispersity, and shape homogeneity, excellent molecular solubility, high chemical stability, and intriguing host-guest chemistry. These properties enable POCs to overcome the limitations of extended porous networks such as metal-organic frameworks (MOFs) and covalent organic frameworks (COFs). However, the applications of POCs in bioimaging remain limited due to the problems associated with their rigid and hydrophobic structures, thus leading to strong aggregation-caused quenching (ACQ) in aqueous biological media. To address this challenge, we report the preparation of aggregation-induced emission (AIE)-active POCs capable of stimuli responsiveness for enhanced bioimaging. We rationally design a hydrophilic, structurally flexible tetraphenylethylene (TPE)-based POC that is almost entirely soluble in aqueous solutions. This POC’s conformationally flexible superstructure allows the dynamic rotation of the TPE-based phenyl rings, thus endowing impressive AIE characteristics for responses to environmental changes such as temperature and viscosity. We employ these notable features in the bioimaging of living cells and obtain good performance, demonstrating that the present AIE-active POCs are suitable candidates for further biological applications.