Photonic characteristics and ex vivo imaging of Escherichia coli-Xen14 within the bovine reproductive tract

The objectives of this study were to (1) characterize the photonic properties of Escherichia coli-Xen14 and (2) conduct photonic imaging of E. coli-Xen14 within bovine reproductive tract segments (RTS) ex vivo (Bos indicus). E. coli-Xen14 was grown for 24 h in Luria Bertani medium (LB), with or without kanamycin (KAN). Every 24 h, for an 8-d interval, inoculums were imaged and photonic emissions (PE) collected. Inoculums were subcultured and plated daily to determine the colony forming units (CFU) and ratio of photon emitters to nonemitters. In the second objective, abattoir-derived bovine reproductive tracts (n = 9) were separated into posterior and anterior vagina, cervix, uterine body, and uterine horns. Two concentrations (3.2 × 10⁸ and 3.2 × 10⁶ CFU/200 μL for relative [High] and [Low], respectively) of E. coli-Xen14 were placed in translucent tubes for detection of PE through RTS. The CFU did not differ (P = 0.31) over time with or without KAN presence; they remained stable with 99.93% and 99.98% photon emitters, respectively. However, PE were lower (P < 0.0001) in cultures containing KAN than in those containing no KAN (629.8 ± 117.7 vs. 3012.0 ± 423.5 relative lights units per second [RLU/sec], respectively). On average, the percentage of PE between RTS, for both concentrations, was higher (P < 0.05) in the uterine body. In summary, E. coli-Xen14 remained stable with respect to the proportions of photon emitters with or without KAN (used to selectively culture E. coli-Xen14). However, KAN presence suppressed photonic activity. The ability to detect PE through various segments of the reproductive tract demonstrated the feasibility of monitoring the presence of E. coli-Xen14 in the bovine reproductive tract ex vivo.     

Fluorescence fluctuations analysis in nanoapertures: physical concepts and biological applications

During the past years, nanophotonics has provided new approaches to study the biological processes below the optical diffraction limit. How single molecules diffuse, bind and assemble can be studied now at the nanometric level, not only in solutions but also in complex and crowded environments such as in live cells. In this context fluorescence fluctuations spectroscopy is a unique tool since it has proven to be easy to use in combination with nanostructures, which are able to confine light in nanometric volumes. We review here recent advances in fluorescence fluctuations’ analysis below the optical diffraction limit with a special focus on nanoapertures milled in metallic films. We discuss applications in the field of single-molecule detection, DNA sequencing and membrane organization, and underscore some potential perspectives of this new emerging technology.     

Near-infrared photons: a non-invasive probe for studying bone blood flow regulation in humans

The study of bone blood flow regulation in humans has always represented a difficult task for the clinician and the researcher. Classical measurement techniques imply the presence of ionizing radiation or contrast agents, or they are slow or cannot be repeated too often in time. In the present review, we would like to give a perspective on how the optical approach might overcome some of these problems and give unique solutions to the study of bone blood flow regulation. We hope that the present contribution will encourage the scientific community to put a greater attention on this approach.     

Optical induction of muscle contraction at the tissue scale through intrinsic cellular amplifiers

The smooth muscle cell is the principal component responsible for involuntary control of visceral organs, including vascular tonicity, secretion, and sphincter regulation. It is known that the neurotransmitters released from nerve endings increase the intracellular Ca²⁺ level in smooth muscle cells followed by muscle contraction. We herein report that femtosecond laser pulses focused on the diffraction‐limited volume can induce intracellular Ca²⁺ increases in the irradiated smooth muscle cell without neurotransmitters, and locally increased intracellular Ca²⁺ levels are amplified by calcium‐induced calcium‐releasing mechanisms through the ryanodine receptor, a Ca²⁺ channel of the endoplasmic reticulum. The laser‐induced Ca²⁺ increases propagate to adjacent cells through gap junctions. Thus, ultrashort‐pulsed lasers can induce smooth muscle contraction by controlling Ca²⁺, even with optical stimulation of the diffraction‐limited volume. This optical method, which leads to reversible and reproducible muscle contraction, can be used in research into muscle dynamics, neuromuscular disease treatment, and nanorobot control. (© 2014 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)