The role of "disaggregation" in optical probe development

Cationic sulfonium functionalization renders Znsalens with high fluorescence, good water solubility and tunable cell-permeability

Introducing cationic sulfonium to the Znsalens skeleton circumvents aggregation arising from intermolecular Zn⋯O interactions (found between Zn and the phenoxyl group of another Znsalen molecule).

Carbon dots with aggregation induced emission enhancement for visual permittivity detection

A simple and rapid bottom-up synthesis route to synthesize TA–CDs by using tannic acid (TA) as the carbon source was developed, which show visual permittivity dependent aggregation induced emission enhancement (AIEE) properties owing to the hampered rotations of the surface groups on CDs and reduced non-radiative decay during CD aggregation.

A stable aggregate system of silyl ether substituted quinacridone and its aggregation-state changes induced by fluoride-ions: inspiration for a dual guaranteed strategy for probe design

Based on the two aggregation-state changes of the THF system of 2, a new dual guaranteed strategy for the real-time naked-eye detection of fluoride-ions was developed.

Borondifluoride complexes of hemicurcuminoids as bio-inspired push-pull dyes for bioimaging

Hemicurcuminoids are based on half of the π-conjugated backbone of curcuminoids. The synthesis of a series of such systems and their borondifluoride complexes is described. The electrochemical and photophysical properties of difluorodioxaborine species were investigated as a function of the nature of electron donor and acceptor groups appended at either terminal positions of the molecular backbone. The emissive character of these dipolar dyes was attributed to an intraligand charge transfer process, leading to fluorescence emission that is strongly dependent on solvent polarity. Quasi-quantitative quenching of fluorescence in high polarity solvents was attributed to photoinduced electron transfer. These dyes were shown to behave as versatile fluorophores. Indeed, they display efficient two-photon excited fluorescence emission leading to high two-photon brightness values. Furthermore, they form nanoparticles in water whose fluorescence emission quantum yield is less than that of the dye in solution, owing to aggregation-induced fluorescence quenching. When cos7 living cells were exposed to these weakly-emitting nanoparticles, one- and two-photon excited fluorescence spectra showed a strong emission within the cytoplasm that originated from the individual molecules. Dye uptake thus involved a disaggregation mechanism at the cell membrane which restored fluorescence emission. This off-on fluorescence switching allows a selective optical monitoring of those molecules that do enter the cell, which offers improved sensitivity and selectivity of detection for bioimaging purposes.

High mobility emissive organic semiconductor

The integration of high charge carrier mobility and high luminescence in an organic semiconductor is challenging. However, there is need of such materials for organic light-emitting transistors and organic electrically pumped lasers. Here we show a novel organic semiconductor, 2,6-diphenylanthracene (DPA), which exhibits not only high emission with single crystal absolute florescence quantum yield of 41.2% but also high charge carrier mobility with single crystal mobility of 34 cm² V⁻¹ s⁻¹. Organic light-emitting diodes (OLEDs) based on DPA give pure blue emission with brightness up to 6,627 cd m⁻² and turn-on voltage of 2.8 V. 2,6-Diphenylanthracene OLED arrays are successfully driven by DPA field-effect transistor arrays, demonstrating that DPA is a high mobility emissive organic semiconductor with potential in organic optoelectronics.

Organic semiconductors with high mobility and strong fluorescence are necessary for optoelectronic devices. Here, Liu et al. show an organic semiconductor, 2,6-diphenylanthracene, satisfying both requirements with mobility of 34 cm² V⁻¹ s⁻¹ and emission of 6,627 cd m⁻² at a turn-on voltage of 2.8 V.

A Dispersion-Dominated Chromogenic Strategy for Colorimetric Sensing of Glutathione at the Nanomolar Level Using Gold Nanoparticles

A dispersion-dominated chromogenic strategy for glutathione sensing is developed. Glutathione prevents the aggregation of arginine-modified gold nanoparticles via mercury-thiol interaction, which allows for glutathione sensing at the nanomolar level (10.9 × 10(-9) m) with facile operation and naked-eye readout.

Chemical Fluorescent Probe for Detection of Aβ Oligomers

Aggregation of amyloid β-peptide (Aβ) is implicated in the pathology of Alzheimer's disease (AD), with the soluble, Aβ oligomeric species thought to be the critical pathological species. Identification and characterization of intermediate species formed during the aggregation process is crucial to the understanding of the mechanisms by which oligomeric species mediate neuronal toxicity and following disease progression. Probing these species proved to be extremely challenging, as evident by the lack of reliable sensors, due to their heterogeneous and transient nature. We describe here an oligomer-specific fluorescent chemical probe, BoDipy-Oligomer (BD-Oligo), developed through the use of the diversity-oriented fluorescent library approach (DOFLA) and high-content, imaging-based screening. This probe enables dynamic oligomer monitoring during fibrillogenesis in vitro and shows in vivo Aβ oligomers staining possibility in the AD mice model.

Near-infrared fluorescence activation probes based on disassembly-induced emission cyanine dye

Currently most of the fluorogenic probes are designed for the detection of enzymes which work by converting the non-fluorescence substrate into the fluorescence product via an enzymatic reaction. On the other hand, the design of fluorogenic probes for non-enzymatic proteins remains a great challenge. Herein, we report a general strategy to create near-IR fluorogenic probes, where a small molecule ligand is conjugated to a novel γ-phenyl-substituted Cy5 fluorophore, for the selective detection of proteins through a non-enzymatic process. Detail mechanistic studies reveal that the probes self-assemble to form fluorescence-quenched J-type aggregate. In the presence of target analyte, bright fluorescence in the near-IR region is emitted through the recognition-induced disassembly of the probe aggregate. This Cy5 fluorophore is a unique self-assembly/disassembly dye as it gives remarkable fluorescence enhancement. Based on the same design, three different fluorogenic probes were constructed and one of them was applied for the no-wash imaging of tumor cells for the detection of hypoxia-induced cancer-specific biomarker, transmembrane-type carbonic anhydrase IX.

The unprecedented J-aggregate formation of rhodamine moieties induced by 9-phenylanthracenyl substitution

We report a substitution of 9-phenylanthracenyl group into rhodamine derivatives that can induce the J-aggregate formation of rhodamine moieties in the aqueous solution upon the addition of a halide ion. From X-ray crystallographic analysis, the dramatic red-shift in the absorption band (i.e. app. 100 nm) originates from the cooperative slipped-stacking of rhodamine and anthracene molecules.

Blue fluorogenic probes for cell plasma membranes fill the gap in multicolour imaging

Newly synthesized blue membrane probes, due to high brightness, large Stokes shift and fluorogenic response, overcome the problem of cell auto-fluorescence and enable multicolor cellular imaging with common green and red markers.

Cu2+-mediated fluorescence switching of gold nanoclusters for the selective detection of clioquinol

In this contribution, a rapid and selective fluorescence switchable strategy was developed for clioquinol by taking gold nanoclusters as probes and Cu²⁺ as mediator, which is applicable to determination of clioquinol in cream with satisfactory results.

Aggregating distyrylpyridinium dye as a bimodal structural probe for G-quadruplex DNA

A coumarin-substituted distyrylpyridinium dye BCVP is proposed as a universal colorimetric and fluorescent probe for the detection of G-quadruplex DNA structures.

Preassembly-driven ratiometric sensing of H2PO4− anions in organic and aqueous environments

The preassembly phenomenon of R1 facilitates novel ratiometric fluorescence sensing of H₂PO₄⁻ in organic and aqueous environments.

Synthesis of a new highly sensitive near-infrared fluorescent iridium(iii) probe and its application for the highly selective detection of glutathione

A new near-IR fluorescent probe (probe 1) based on the IR 780 skeleton exhibits high selectivity and sensitivity towards Ir(iii) in an EtOH/H₂O solution. The probe 1–Ir(iii) complex was also used for the highly selective detection of glutathione.

Restriction of intramolecular motions: the general mechanism behind aggregation-induced emission

Aggregation-induced emission (AIE) has been harnessed in many systems through the principle of restriction of intramolecular rotations (RIR) based on mechanistic understanding from archetypal AIE molecules such as tetraphenylethene (TPE). However, as the family of AIE-active molecules grows, the RIR model cannot fully explain some AIE phenomena. Here, we report a broadening of the AIE mechanism through analysis of 10,10',11,11'-tetrahydro-5,5'-bidibenzo[a,d][7]annulenylidene (THBDBA), and 5,5'-bidibenzo[a,d][7]annulenylidene (BDBA). Analyses of the computational QM/MM model reveal that the novel mechanism behind the AIE of THBDBA and BDBA is the restriction of intramolecular vibration (RIV). A more generalized mechanistic understanding of AIE results by combining RIR and RIV into the principle of restriction of intramolecular motions (RIM).

A peptide probe for the detection of neurokinin-1 receptor by disaggregation enhanced fluorescence and magnetic resonance signals

We report a novel peptide probe for the detection of neurokinin-1 receptor using disaggregation-caused signal enhancement. The probe was obtained via the aggregation of a modified substance P in a terpyridine-Fe (II) complex with Gd (III)-DOTA into well-defined nanostructures, which effectively weaken ligand fluorescence and slow the exchange rate of inner-sphere water molecules. This probe disaggregates upon binding to the neurokinin-1 receptor and activates the contrast agents to generate a fluorescent signal that positively enhances magnetic resonance imaging contrast and allows for the detection of overexpressed receptors on tumor cells and the identification of lung cancer using serum samples.

Self-assembling small molecules for the detection of important analytes

Self-assembling small molecules including those capable of forming hydrogels have been used to detect important analytes.

Milk quality control: instant and quantitative milk fat determination with a BODIPY sensor-based fluorescence detector

The first fluorescent sensor for milk fat was developed.

A self-assembled π-conjugated system as an anti-proliferative agent in prostate cancer cells and a probe for intra-cellular imaging

Herein, self-assembled π-conjugated systems derived from renewable resource are reported as a probe for intra-cellular imaging and an anti-proliferative agent for PC3 cells.