4,894 research outputs found
Towards Picogram Detection of Superparamagnetic Iron-Oxide Particles Using a Gradiometric Receive Coil
Superparamagnetic iron-oxide nanoparticles can be used in a variety of
medical applications like vascular or targeted imaging. Magnetic particle
imaging (MPI) is a promising tomographic imaging technique that allows
visualizing the 3D nanoparticle distribution concentration in a non-invasive
manner. The two main strengths of MPI are high temporal resolution and high
sensitivity. While the first has been proven in the assessment of dynamic
processes like cardiac imaging, it is unknown how far the detection limit of
MPI can be lowered. Within this work, we will present a highly sensitive
gradiometric receive-coil unit combined with a noise-matching network tailored
for the measurement of mice. The setup is capable of detecting 5 ng of iron in
vitro at 2.14 sec acquisition time. In terms of iron concentration we are able
to detect 156 {\mu}g/L marking the lowest value that has been reported for an
MPI scanner so far. In vivo MPI mouse images of a 512 ng bolus at 21.5 ms
acquisition time allow for capturing the flow of an intravenously injected
tracer through the heart of a mouse. Since it has been rather difficult to
compare detection limits across MPI publications we propose guidelines
improving the comparability of future MPI studies.Comment: 15 Pages, 7 Figures, V2: Changed the initials of Author Kannan M
Krishnan, added two citations, corrected typo
Nonlinear acousto-magneto-plasmonics
We review the recent progress in experimental and theoretical research of
interactions between the acoustic, magnetic and plasmonic transients in hybrid
metal-ferromagnet multilayer structures excited by ultrashort laser pulses. The
main focus is on understanding the nonlinear aspects of the acoustic dynamics
in materials as well as the peculiarities in the nonlinear optical and
magneto-optical response. For example, the nonlinear optical detection is
illustrated in details by probing the static magneto-optical second harmonic
generation in gold-cobalt-silver trilayer structures in Kretschmann geometry.
Furthermore, we show experimentally how the nonlinear reshaping of giant
ultrashort acoustic pulses propagating in gold can be quantified by
time-resolved plasmonic interferometry and how these ultrashort optical pulses
dynamically modulate the optical nonlinearities. The effective medium
approximation for the optical properties of hybrid multilayers facilitates the
understanding of novel optical detection techniques. In the discussion we
highlight recent works on the nonlinear magneto-elastic interactions, and
strain-induced effects in semiconductor quantum dots.Comment: 30 pages, 12 figures, to be published as a Topical Review in the
Journal of Optic
Imaging of Magnetic Nanoparticles using Magnetoelectric Sensors
Imaging of magnetic nanoparticles offers a variety of promising medical applications for therapeutics and diagnostics. Using magnetic nanoparticles as tracer material for imaging allows for the non-invasive detection of spatial distributions of nanoparticles that can give information about diseases or can be used in preventive medicine. Imaging biodistributions of magnetically labeled cells offers applicability for tissue engineering, as a means to monitor cell growth within artificial scaffolds non-destructively. In the presented work, the capabilities of an imaging system for magnetic nanoparticles via magnetoelectric sensors are investigated. The investigated technique, called Magnetic Particle Mapping, is based on the detection of the nonlinear magnetic response of magnetic nanoparticles. A resonant magnetoelectric sensor is used for frequency selective measurements of the nanoparticles magnetic response. Extensive modeling was performed that enabled proper imaging of magnetic nanoparticle distributions. Fundamental limitations of the imaging system were derived to describe resolution in correspondence to signal-to-noise ratios. Incorporation of additional parameters in the imaging system for the data analysis resulted in an algorithm for a more robust reconstruction of spatial particle distributions, increasing its imaging capabilities. Experimental investigations of the imaging system show the capabilities for imaging of cell densities using magnetically labeled cells. Furthermore, resolution limitations were investigated and differentiation of different particle types in imaging was shown, referred to as ”colored” imaging. The imaging of biodistributions of magnetically labeled cells thus enable exciting perspectives on further research and possible applications in tissue engineering
Development of Molecular Contrast-enhanced Imaging for Optical Coherence Tomography
Biological imaging techniques that are able to detect a contrast-enhanced signal from the target molecules have been widely applied to various techniques in the imaging field. The complex biological environment provides numerous and more efficient pathways along which the chromophores (light absorber) may release its energy. This energy can provide not only morphological information, but also specific molecular information such as a biochemical map of a sample. All diseases correlate with both morphological and biochemical changes.
Optical coherence tomography (OCT) system is one of the biological imaging techniques. OCT has widely been applied to many medical/clinical fields, giving benefit from a penetration depth of a few millimeters while maintaining a spatial resolution on the order of a micron. Unfortunately, OCT lacks the straightforward functional molecular imaging extensions available for other technologies, e.g. confocal fluorescence microscopy and fluorescence diffuse optical tomography. This is largely because incoherent processes such as fluorescence emission and Raman scattering are not readily detectable with low coherence interferometry that is the central technique that underlies all OCT systems. Despite a drawback of molecular imaging with OCT, it is highly desirable to measure not only morphological, but also molecular information from either endogenous or exogenous molecules.
In order to overcome the limitation of molecular contrast imaging for OCT, our group has been researched the hybrid OCT imaging technique and a new exogenous contrast agent. Our contrast-enhanced imaging technique integrates OCT with a well-researched and well-established technique: two-colored pump-probe absorption spectroscopy. Our novel imaging technique is called Pump-Probe OCT (PPOCT). Based upon current successful results, molecular imaging with OCT potentially gives us the ability to identify pathologies. In order to expand the capacity of PPOCT, this dissertation focuses on development of molecular contrast-enhanced imaging for optical coherence tomography (OCT).
In the first phase of the research, we developed and optimized for sensitivity a two-color ground state recovery Pump-Probe Optical Coherence Tomography (gsrPPOCT) system and signal algorithm to measure the contrast-enhanced signal of endogenous and exogenous contrast agents such as Hemoglobin (Hb) and Methylene blue (MB) from in vivo samples. Depending on the absorption peak of a target molecule, the pump light sources for PPOCT used 532nm Q-switched laser or 663nm diode laser. Based on different experimental application, Ti:sapp or SLD of 830nm center wavelength were utilized. The PPCOT system was firstly used to image Hb of in vivo vasulature in a Xenopus laevis as the endogenous contrast agent and a larval stage zebrafish using MB as the exogenous contrast agent via transient changes in light absorption. Their morphological in addition to molecular specific information from a live animal was described. The incorporation of a pump laser in an otherwise typical spectrometer based OCT system is sufficient to enable molecular imaging with PPOCT.
In the second phase of this research, based on endoscopic molecular contrast-enhanced applications for OCT, we invented an ultra-wideband lensless fiber optic rotary joint based on co-aligning two optical fibers has excellent performance (~0.38 dB insertion loss). The developed rotary joint can cover a wavelength range of at least 355- 1360 nm with single mode, multimode, and double clad fibers with rotational velocities up to 8800 rpm (146 Hz).
In the third phase of this research, we developed and manufactured a microencapsulated methylene blue (MB) contrast agent for PPOCT. The poly lactic coglycolic acid (PLGA) microspheres loaded with MB offer several advantages over bare MB. The microsphere encapsulation improves the PPOCT signal both by enhancing the scattering and preventing the reduction of MB to leucomethylene blue. The surface of the microsphere can readily be functionalized to enable active targeting of the contrast agent without modifying the excited state dynamics of MB that enable PPOCT imaging. Both MB and PLGA are used clinically. PLGA is FDA approved and used in drug delivery and tissue engineering applications. 2.5 µm diameter microspheres were synthesized with an inner core containing 0.01% (w/v) aqueous MB. As an initial demonstration the MB microspheres were imaged in a 100 µm diameter capillary tube submerged in a 1% intralipid emulsion. By varying the oxygen concentration both 0% and 21%, we observed he lifetime of excited triple state using time-resolved Pump-Probe spectroscopy and also the relative phase shift between the pump and probe is a reliable indicator of the oxygen concentration. Furthermore, these results are in good agreement with our theoretical predictions. This development opens up the possibility of using MB for 3-D oxygen sensing with PPOCT
Development of Molecular Contrast-enhanced Imaging for Optical Coherence Tomography
Biological imaging techniques that are able to detect a contrast-enhanced signal from the target molecules have been widely applied to various techniques in the imaging field. The complex biological environment provides numerous and more efficient pathways along which the chromophores (light absorber) may release its energy. This energy can provide not only morphological information, but also specific molecular information such as a biochemical map of a sample. All diseases correlate with both morphological and biochemical changes.
Optical coherence tomography (OCT) system is one of the biological imaging techniques. OCT has widely been applied to many medical/clinical fields, giving benefit from a penetration depth of a few millimeters while maintaining a spatial resolution on the order of a micron. Unfortunately, OCT lacks the straightforward functional molecular imaging extensions available for other technologies, e.g. confocal fluorescence microscopy and fluorescence diffuse optical tomography. This is largely because incoherent processes such as fluorescence emission and Raman scattering are not readily detectable with low coherence interferometry that is the central technique that underlies all OCT systems. Despite a drawback of molecular imaging with OCT, it is highly desirable to measure not only morphological, but also molecular information from either endogenous or exogenous molecules.
In order to overcome the limitation of molecular contrast imaging for OCT, our group has been researched the hybrid OCT imaging technique and a new exogenous contrast agent. Our contrast-enhanced imaging technique integrates OCT with a well-researched and well-established technique: two-colored pump-probe absorption spectroscopy. Our novel imaging technique is called Pump-Probe OCT (PPOCT). Based upon current successful results, molecular imaging with OCT potentially gives us the ability to identify pathologies. In order to expand the capacity of PPOCT, this dissertation focuses on development of molecular contrast-enhanced imaging for optical coherence tomography (OCT).
In the first phase of the research, we developed and optimized for sensitivity a two-color ground state recovery Pump-Probe Optical Coherence Tomography (gsrPPOCT) system and signal algorithm to measure the contrast-enhanced signal of endogenous and exogenous contrast agents such as Hemoglobin (Hb) and Methylene blue (MB) from in vivo samples. Depending on the absorption peak of a target molecule, the pump light sources for PPOCT used 532nm Q-switched laser or 663nm diode laser. Based on different experimental application, Ti:sapp or SLD of 830nm center wavelength were utilized. The PPCOT system was firstly used to image Hb of in vivo vasulature in a Xenopus laevis as the endogenous contrast agent and a larval stage zebrafish using MB as the exogenous contrast agent via transient changes in light absorption. Their morphological in addition to molecular specific information from a live animal was described. The incorporation of a pump laser in an otherwise typical spectrometer based OCT system is sufficient to enable molecular imaging with PPOCT.
In the second phase of this research, based on endoscopic molecular contrast-enhanced applications for OCT, we invented an ultra-wideband lensless fiber optic rotary joint based on co-aligning two optical fibers has excellent performance (~0.38 dB insertion loss). The developed rotary joint can cover a wavelength range of at least 355- 1360 nm with single mode, multimode, and double clad fibers with rotational velocities up to 8800 rpm (146 Hz).
In the third phase of this research, we developed and manufactured a microencapsulated methylene blue (MB) contrast agent for PPOCT. The poly lactic coglycolic acid (PLGA) microspheres loaded with MB offer several advantages over bare MB. The microsphere encapsulation improves the PPOCT signal both by enhancing the scattering and preventing the reduction of MB to leucomethylene blue. The surface of the microsphere can readily be functionalized to enable active targeting of the contrast agent without modifying the excited state dynamics of MB that enable PPOCT imaging. Both MB and PLGA are used clinically. PLGA is FDA approved and used in drug delivery and tissue engineering applications. 2.5 µm diameter microspheres were synthesized with an inner core containing 0.01% (w/v) aqueous MB. As an initial demonstration the MB microspheres were imaged in a 100 µm diameter capillary tube submerged in a 1% intralipid emulsion. By varying the oxygen concentration both 0% and 21%, we observed he lifetime of excited triple state using time-resolved Pump-Probe spectroscopy and also the relative phase shift between the pump and probe is a reliable indicator of the oxygen concentration. Furthermore, these results are in good agreement with our theoretical predictions. This development opens up the possibility of using MB for 3-D oxygen sensing with PPOCT
Gradient metasurfaces: a review of fundamentals and applications
In the wake of intense research on metamaterials the two-dimensional
analogue, known as metasurfaces, has attracted progressively increasing
attention in recent years due to the ease of fabrication and smaller insertion
losses, while enabling an unprecedented control over spatial distributions of
transmitted and reflected optical fields. Metasurfaces represent optically thin
planar arrays of resonant subwavelength elements that can be arranged in a
strictly or quasi periodic fashion, or even in an aperiodic manner, depending
on targeted optical wavefronts to be molded with their help. This paper reviews
a broad subclass of metasurfaces, viz. gradient metasurfaces, which are devised
to exhibit spatially varying optical responses resulting in spatially varying
amplitudes, phases and polarizations of scattered fields. Starting with
introducing the concept of gradient metasurfaces, we present classification of
different metasurfaces from the viewpoint of their responses, differentiating
electrical-dipole, geometric, reflective and Huygens' metasurfaces. The
fundamental building blocks essential for the realization of metasurfaces are
then discussed in order to elucidate the underlying physics of various physical
realizations of both plasmonic and purely dielectric metasurfaces. We then
overview the main applications of gradient metasurfaces, including waveplates,
flat lenses, spiral phase plates, broadband absorbers, color printing,
holograms, polarimeters and surface wave couplers. The review is terminated
with a short section on recently developed nonlinear metasurfaces, followed by
the outlook presenting our view on possible future developments and
perspectives for future applications.Comment: Accepted for publication in Reports on Progress in Physic
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