56,989 research outputs found
Applications Of Microspectroscopy, Hyperspectral Chemical Imaging And Fluorescence Microscopy In Chemistry, Biochemistry, Biotechnology, Molecular And Cell Biology
Chemical imaging is a technique for the simultaneous measurement of spectra (chemical information) and images or pictures (spatial information)^1,2^. The technique is most often applied to either solid or gel samples, and has applications in chemistry, biology^3-8^, medicine^9,10^, pharmacy^11^ (see also for example: Chemical Imaging Without Dyeing), food science, Food Physical Chemistry, Biotechnology^12,13^, Agriculture and industry. NIR, IR and Raman chemical imaging is also referred to as hyperspectral, spectroscopic, spectral or multi-spectral imaging (also see micro-spectroscopy). However, other ultra-sensitive and selective, chemical imaging techniques are also in use that involve either UV-visible or fluorescence microspectroscopy
Plasmonic antennas and zero mode waveguides to enhance single molecule fluorescence detection and fluorescence correlation spectroscopy towards physiological concentrations
Single-molecule approaches to biology offer a powerful new vision to
elucidate the mechanisms that underpin the functioning of living cells.
However, conventional optical single molecule spectroscopy techniques such as
F\"orster fluorescence resonance energy transfer (FRET) or fluorescence
correlation spectroscopy (FCS) are limited by diffraction to the nanomolar
concentration range, far below the physiological micromolar concentration range
where most biological reaction occur. To breach the diffraction limit, zero
mode waveguides and plasmonic antennas exploit the surface plasmon resonances
to confine and enhance light down to the nanometre scale. The ability of
plasmonics to achieve extreme light concentration unlocks an enormous potential
to enhance fluorescence detection, FRET and FCS. Single molecule spectroscopy
techniques greatly benefit from zero mode waveguides and plasmonic antennas to
enter a new dimension of molecular concentration reaching physiological
conditions. The application of nano-optics to biological problems with FRET and
FCS is an emerging and exciting field, and is promising to reveal new insights
on biological functions and dynamics.Comment: WIREs Nanomed Nanobiotechnol 201
Calibrating evanescent-wave penetration depths for biological TIRF microscopy
Roughly half of a cells proteins are located at or near the plasma membrane.
In this restricted space the cell senses its environment, signals to its
neighbors and ex-changes cargo through exo- and endocytotic mechanisms. Ligands
bind to receptors, ions flow across channel pores, and transmitters and
metabolites are transported against con-centration gradients. Receptors, ion
channels, pumps and transporters are the molecular substrates of these
biological processes and they constitute important targets for drug discovery.
Total internal reflection fluorescence microscopy suppresses background from
cell deeper layers and provides contrast for selectively imaging dynamic
processes near the basal membrane of live-cells. The optical sectioning of
total internal reflection fluorescence is based on the excitation confinement
of the evanescent wave generated at the glass-cell interface. How deep the
excitation light actually penetrates the sample is difficult to know, making
the quantitative interpretation of total internal reflection fluorescence data
problematic. Nevertheless, many applications like super-resolution microscopy,
colocalization, fluorescence recovery after photobleaching, near-membrane
fluorescence recovery after photobleaching, uncaging or
photo-activation-switching, as well as single-particle tracking require the
quantitative interpretation of evanescent-wave excited images. Here, we review
existing techniques for characterizing evanescent fields and we provide a
roadmap for comparing total internal reflection fluorescence data across
images, experiments, and laboratories.Comment: 18 text pages, 7 figures and one supplemental figur
Near Infrared Microspectroscopy, Fluorescence Microspectroscopy, Infrared Chemical Imaging and High-Resolution Nuclear Magnetic Resonance Analysis of Soybean Seeds, Embryos and Single Cells
Chemical analysis of soybean seeds, somatic embryos and single cells were carried out by Fourier Transform Infrared (FT-IR), Fourier Transform Near Infrared (FT-NIR) Microspectroscopy, Fluorescence and High-Resolution NMR (HR-NMR). The first FT-NIR chemical images of biological systems approaching 1 micron (1μ) resolution are presented here. Chemical images obtained by FT-NIR and FT-IR Microspectroscopy are presented for oil in soybean seeds and somatic embryos under physiological conditions. FT-NIR spectra of oil and proteins were obtained for volumes as small as 2μ3. Related, HR-NMR analyses of oil contents in somatic embryos are also presented here with nanoliter precision. Such 400 MHz 1H NMR analyses allowed the selection of mutagenized embryos with higher oil content (e.g. ~20%) compared to non-mutagenized control embryos. Moreover, developmental changes in single soybean seeds and/or somatic embryos may be monitored by FT-NIR with a precision approaching the picogram level. Indeed, detailed chemical analyses of oils and phytochemicals are now becoming possible by FT-NIR Chemical Imaging/ Microspectroscopy of single cells. The cost, speed and analytical requirements of plant breeding and genetic selection programs are fully satisfied by FT-NIR spectroscopy and Microspectroscopy for soybeans and soybean embryos. FT-NIR Microspectroscopy and Chemical Imaging are also shown to be potentially important in functional Genomics and Proteomics research through the rapid and accurate detection of high-content microarrays (HCMA). Multi-photon (MP), pulsed femtosecond laser NIR Fluorescence Excitation techniques were shown to be capable of Single Molecule Detection (SMD). Therefore, such powerful techniques allow for the most sensitive and reliable quantitative analyses to be carried out both in vitro and in vivo. Thus, MP NIR excitation for Fluorescence Correlation Spectroscopy (FCS) allows not only single molecule detection, but also molecular dynamics and high resolution, submicron imaging of femtoliter volumes inside living cells and tissues. These novel, ultra-sensitive and rapid NIR/FCS analyses have numerous applications in important research areas, such as: agricultural biotechnology, food safety, pharmacology, medical research and clinical diagnosis of viral diseases and cancers
Multi-confocal Fluorescence Correlation Spectroscopy : experimental demonstration and potential applications for living cell measurements
We report, for the first time, a multi-confocal Fluorescence Correlation
Spectroscopy (mFCS) technique which allows parallel measurements at different
locations, by combining a Spatial Light Modulator (SLM), with an Electron
Multiplying-CCD camera (EM-CCD). The SLM is used to produce a series of laser
spots, while the pixels of the EM-CCD play the roles of virtual pinholes. The
phase map addressed to the SLM is calculated by using the spherical wave
approximation and makes it possible to produce several diffraction limited
laser spots, either aligned or spread over the field of view. To attain fast
enough imaging rates, the camera has been used in different acquisition modes,
the fastest of which leads to a time resolution of 100 s. We qualified the
experimental set-up by using solutions of sulforhodamine G in glycerol and
demonstrated that the observation volumes are similar to that of a standard
confocal set-up. To demonstrate that our mFCS method is suitable for
intracellular studies, experiments have been conducted on two stable cell
lines: mouse embryonic fibroblasts expressing eGFP-actin and H1299 cells
expressing the heat shock factor fusion protein HSF1-eGFP. In the first case we
could recover, by analyzing the auto-correlation curves, the diffusion constant
of G-actin within the cytoplasm, although we were also sensitive to the complex
network of interactions with F-actin. Concerning HSF1, we could clearly observe
the modifications of the number of molecules and of the HSF1 dynamics during
heat shock
Multiphoton Label-Free ex-vivo imaging using a custom-built dual-wavelength microscope with chromatic aberrations compensation
Label-Free Multiphoton Microscopy is a very powerful optical microscopy that
can be applied to study samples with no need for exogenous fluorescent probes,
keeping the main benefits of a Multiphoton approach, like longer penetration
depths and intrinsic optical sectioning, while opening the possibility of
serial examinations with different kinds of techniques. Among the many
variations of Label-Free MPM, Higher Harmonic Generation (HHG) is one of the
most intriguing due to its generally low photo-toxicity, which enables the
examination of specimens particularly susceptible to photo-damages. HHG and
common Two-Photon Microscopy (TPM) are well-established techniques, routinely
used in several research fields. However, they require a significant amount of
fine-tuning in order to be fully exploited and, usually, the optimized
conditions greatly differ, making them quite difficult to perform in parallel
without any compromise on the extractable information. Here we present our
custom-built Multiphoton microscope capable of performing simultaneously TPM
and HHG without any kind of compromise on the results thanks to two, separate,
individually optimized laser sources with full chromatic aberration
compensation. We also apply our setup to the examination of a plethora of ex
vivo samples in order to prove the significant advantages of our approach
A general perspective of the characterization and quantification of nanoparticles: Imaging, spectroscopic, and separation techniques
This article gives an overview of the different techniques used to identify, characterize, and quantify engineered nanoparticles (ENPs). The state-of-the-art of the field is summarized, and the different characterization techniques have been grouped according to the information they can provide. In addition, some selected applications are highlighted for each technique. The classification of the techniques has been carried out according to the main physical and chemical properties of the nanoparticles such as morphology, size, polydispersity characteristics, structural information, and elemental composition. Microscopy techniques including optical, electron and X-ray microscopy, and separation techniques with and without hyphenated detection systems are discussed. For each of these groups, a brief description of the techniques, specific features, and concepts, as well as several examples, are described.Junta de AndalucĂa FQM-5974CEI-Biotic Granada CEI2013- MP-1
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