Multimodal imaging needle combining optical coherence tomography and fluorescence for imaging of live breast cancer cells labeled with a fluorescent analog of tamoxifen.

SIGNIFICANCE: Imaging needles consist of highly miniaturized focusing optics encased within a hypodermic needle. The needles may be inserted tens of millimeters into tissue and have the potential to visualize diseased cells well beyond the penetration depth of optical techniques applied externally. Multimodal imaging needles acquire multiple types of optical signals to differentiate cell types. However, their use has not previously been demonstrated with live cells. AIM: We demonstrate the ability of a multimodal imaging needle to differentiate cell types through simultaneous optical coherence tomography (OCT) and fluorescence imaging. APPROACH: We characterize the performance of a multimodal imaging needle. This is paired with a fluorescent analog of the therapeutic drug, tamoxifen, which enables cell-specific fluorescent labeling of estrogen receptor-positive (ER+) breast cancer cells. We perform simultaneous OCT and fluorescence in situ imaging on MCF-7 ER+ breast cancer cells and MDA-MB-231 ER- cells. Images are compared against unlabeled control samples and correlated with standard confocal microscopy images. RESULTS: We establish the feasibility of imaging live cells with these miniaturized imaging probes by showing clear differentiation between cancerous cells. CONCLUSIONS: Imaging needles have the potential to aid in the detection of specific cancer cells within solid tissue.

A mechanism-based GlcNAc-inspired cyclophellitol inactivator of the peptidoglycan recycling enzyme NagZ reverses resistance to ß-lactams in Pseudomonas aeruginosa.

The development of a potent mechanism-based inactivator of NagZ, an enzyme critical to the production of inducible AmpC ß-lactamase in Gram-negative bacteria, is presented. This inactivator significantly reduces MIC values for important ß-lactams against a clinically relevant strain of Pseudomonas aeruginosa.

Angled Vortex Fluidic Mediated Multicomponent Photocatalytic and Transition Metal-Catalyzed Reactions.

The dynamic thin film formed in an angled rapidly rotating tube in a vortex fluidic device (VFD) is effective in facilitating multicomponent reactions (MCRs) as photocatalytic or metal-mediated processes. Here, we demonstrate the utility of the VFD by using two known MCRs, an Ugi-type three component reaction and an A3 -coupling reaction. The Ugi-type reaction can be done in either confined or continuous-flow modes of operation of the microfluidic platform whereas the A3 -coupling reaction was optimized for the confined mode of operation. The examples tested gave excellent yields with short reaction times.

A new selective fluorescent probe based on tamoxifen.

Developing targeted validation probes that can interrogate biology is of interest for both chemists and biologists. The synthesis of suitable compounds provides a means for avoiding the costly labeling of cells with specific antibodies and the bias associated with the interpretation of biological validation experiments. The chemotherapeutic agent, tamoxifen has been routinely used in the treatment of breast cancer for decades. Once metabolized, the active form of tamoxifen (4-hydroxytamoxifen) competes with the binding of estrogens to the estrogen receptors (ER). Its selectivity in ER modulation makes it an ideal candidate for the development of materials to be used as chemical probes. Here we report the synthesis of a fluorescent BODIPY®FL conjugate of tamoxifen linked through an ethylene glycol moiety, and present proof-of-principle results in ER positive and ER negative cell lines. Optical microscopy indicates that the fluorescent probe binds selectively to tamoxifen sensitive breast cancer cell lines. The compound showed no affinity for the tamoxifen resistant breast cancer lines. The specificity of the new compound make it a valuable addition to the chemical probe tool kit for estrogen receptors.

Fluorescent triphenyl substituted maleimide derivatives: synthesis, spectroscopy and quantum chemical calculations.

In this paper we describe a semi-empirical quantum method for predicting the wavelength of maximum fluorescence excitation and emission for several known and new maleimide derivatives. All new maleimides, containing a N-Benzyl attachment, were successfully synthesised via a tandem Suzuki reaction with aryl boronic acids containing either an electron donating, electron withdrawing functional groups. Absorption and emission spectra calculated using the semi-empirical AM1 method with excited state ZINDO calculations proved more reliable than either Hartree-Fock Configuration interaction or time dependent density functional methods. Calculated absorption and emission wavelengths were compared with 26 experimental spectra from known or newly synthesised maleimides and found to have provide reasonable predictions, with an average deviation of less the 6% for absorption maxima and less than 4% for emission peaks. The described method provides a strong benchmark for the accuracy that can be expected from theoretical predictions of fluorescence spectra.

Rapid evaluation of Antrodia camphorata natural products and derivatives in tumourigenic liver progenitor cells with a novel cell proliferation assay.

We report the syntheses of five natural product maleimide and maleic anhydrides from the mushroom Antrodia camphorata. The ability of these compounds to affect proliferation in non-tumourigenic and tumourigenic liver progenitor cell lines was monitored by the Cellscreen system, a novel and nondestructive rapid-screening instrument. Additionally, a range of new aryl-functionalised differentiated derivatives were prepared through a Suzuki cross-coupling reaction to influence cell-growth effects. Several derivatives radically slowed the proliferation of liver progenitor cells; however, of particular interest were two maleic anhydride derivatives containing aryl tethers. These analogues demonstrated selectivity for limiting the proliferation of tumourigenic progenitor cells in comparison with their non-tumourigenic counterparts. Also highlighted is the application of the Cellscreen system in medicinal chemistry to rapidly measure the effect of compound libraries on cell proliferation.