Electron Transfer based Ultra-bright Organic Afterglow Nanoprobe for Accurate Molecular Imaging in Mice

Afterglow luminescence can greatly improve the signal-to-background ratio (SBR) of molecule imaging in living animal owing to the no need of real-time light excitation. However, the relatively low luminescence of afterglow nanoprobe and attenuation of maximum intensity (afterglow photobleaching) usually lead to the insufficient sensitivity and the inaccurate quantification for repeated molecular imaging. Furthermore, the requirement of high power of light excitation (up to 1 W/cm2) may result in the inevitable phototoxicity, and the long acquisition time (up to 1 min) make it difficult to detect the rapid biological events. Herein, we design electron-rich trianthracene derivatives (TA)-based organic afterglow nanoparticles (TA-NPs) for high-sensitive, safe, lossless and longitudinal molecular imaging. Notably, a great enhancement of afterglow luminescence performance over the previous reported afterglow nanoparticles is achieved though electron transfer engineering (Table 1): Specifically, TA-NPs can be excited by room light with ultra-low power (58 µW/cm2) and with ultra-short acquisition time (0.01 s). The luminescent intensity of TA-NPs is ~ 500-fold of commonly used organic MEHPPV-based nanoparticles. Negligible afterglow photobleaching in mice is observed even after re-excitation for more than 15 cycles. Such ultra-bright afterglow enables the deep-tissue imaging (up to 6.0 cm) and the ultra-fast afterglow imaging of freely-moving mice in waken state. Moreover, TA-NPs can dynamically and accurately visualize subcutaneous tumor, orthotopic glioma and distinguish the plaque in carotid atherosclerosis. Finally, we develop an afterglow nanoprobe (TA-BHQ), activated only in the presence of Granzyme B, for tracking the time-sensitive Granzyme B activity as a direct way to monitor immunotherapeutic responses.

Photo-Luminescence study of Ba3Gd1-x(BO3)3 : X Ce3+ phosphor

The polycrystalline powder sample of Ce3+ activated barium gadolinium borate phosphors Ba3Gd1-x(BO3)3 : X Ce3+(0.01 ≤ X ≤ 0.06 ) are prepared by solution combustion. Formation of phosphor in desired crystalline phase confirmed by powder XRD characterization & FTIR. A SEM image shows the irregular grains with average particle size 2.5μm. The excitation spectrum consists of a single broad absorption band from 200 to 400 nm with the prominent excitation peak at 343 nm [2F5/2 to 5D1 of Ce3+ ions]. Strongest emission peak of 488nm [5D1→ 2F5/2] and weak of 501nm [5D1→ 2F7/2] wavelength which is of blue light is observed at 343nm UV light excitation. Ba3Gd1-x(BO3)3 : X Ce3+ phosphor emits blue light under UV excitation. Maximum PL emission takes place at 3 mole percentage of Ce3+. Concentration quenching for Ce3+ ions is studied. Hence Ba3Gd1-x(BO3)3 : X Ce3+ is new UV excited blue emitting phosphor useful for UV/Blue chip WLEDs.

Resonant light scattering from dielectric ring of rectangular cross section

In this paper we present the results of numerical calculations of electromagnetic properties for cylindrical ring resonators (RRs) with rectangular cross-section and a dielectric permittivity corresponding to silicon ε = 12. The calculation of the scattering spectrum (Radar Cross Section) and the field distribution of the modes were performed at in-plane polarized light excitation. The presence of four side walls in the RRs determines a richer spectrum of eigenmodes in comparison with cylindrical whispering gallery modes of disk resonators and creates more possibilities and diversity for their practical applications.

Porous silicon pillar structures/photosynthetic reaction centre protein hybrid for bioelectronic applications

Photosynthetic biomaterials have attracted considerable attention at different levels of the biological organisation, from molecules to the biosphere, due to a variety of artificial application possibilities. During photosynthesis, the first steps of the conversion of light energy into chemical energy take place in a pigment–protein complex, called reaction centre (RC). In our experiments photosynthetic reaction centre protein, purified from Rhodobacter sphaeroides R-26 purple bacteria, was bound to porous silicon pillars (PSiP) after the electropolymerisation of aniline onto the surface. This new type of biohybrid material showed remarkable photoactivity in terms of measured photocurrent under light excitation in an electrochemical cell. The photocurrent was found to increase considerably after the addition of ubiquinone (UQ-0), an e−-acceptor mediator of the RC. The photoactivity of the complex was found to decrease by the addition of terbutryn, the chemical which inhibits the e−-transport on the acceptor side of the RC. In addition to the generation of sizeable light-induced photocurrents, using the PSiP/RC photoactive hybrid nanocomposite material, the system was found to be sensitive towards RC inhibitors and herbicides. This highly ordered patterned 3D structure opens new solution for designing low-power (bio-)optoelectronic, biophotonic and biosensing devices. Graphical abstract

Effect of Rate and Quantum Yield of 1-alkyl-2-(arylazo) Imidazoles on the Surface of Silver Nps

1-Alkyl-2-(arylazo)imidazole(RaaiR/) exists in trans-structure about –N=N- bond at ambient condition. Upon optical excitation in UV region the trans-RaaiR/ isomerises to cis-RaaiR/. The photochromism is very susceptible to internal substituents and external environment like solvent polarity, viscosity and presence of innocent foreign molecule. The changes from cis-to-trans occurs slowly in visible light excitation it has significantly faster rate at higher temperature. In this work we have studied the effect of silver nanoparticle on the photochromic activity of RaaiR/. The quantum yield of the photoisomerisation is dropped by 9-27% in inclusion phase AgNPs@RaaiR/ than free state and the order of rate is: free state > silver nano particle. The activation energy (Ea) of cis to trans isomerisation is also diminished compared to free state of photochrome.