Optical imaging in tissue with X-ray excited luminescent sensors

Chen, Hongyu; Longfield, David E.; Varahagiri, Venkata S.; Nguyen, KhanhVan T.; Patrick, Amanda L.; Qian, Haijun; VanDerveer, Donald G.; Anker, Jeffrey N.

doi:10.1039/c0an00931h

Cited by 36 publications

(41 citation statements)

References 43 publications

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“…[15] The ability of X-ray excited optical luminescence to study silver dissolution through tissue in one dimension was also demonstrated. [16] We also showed that hollow X-ray scintillators could be used to monitor drug release in vitro and the luminescent signal could be detected at one wavelength in living mice, however, luminescent signal was detected by only irradiating a single location in living mice (not a scanned or two dimensional image) and no in vivo drug release monitoring was achieved. [17] Herein, we extended our previous work and developed an XELCI technique to non-invasively map local pH variation due to bacterial metabolic activity in two dimensions through thick tissue with high spatial resolution.…”

Section: Introductionmentioning

confidence: 99%

X‐Ray Excited Luminescence Chemical Imaging of Bacterial Growth on Surfaces Implanted in Tissue

Wang

Raval

Tzeng

et al. 2015

Adv Healthcare Materials

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We develop a pH sensor film that can be coated on an implant surface and imaged using a combination of X-ray excitation and visible spectroscopy to monitor bacterial infection and treatment of implanted medical devices (IMDs) through tissue. X-ray scintillators in the pH sensor film generate light when an X-ray beam irradiates them. This light first passes through a layer containing pH indicator that alters the spectrum according to pH, then passes through tissue where it is detected by a spectrometer. A reference region on the film is used to account for spectral distortion from wavelength-dependent absorption and scattering in the tissue. pH images are acquired by moving the sample relative to the X-ray beam and collecting a spectrum at each location, with a spatial resolution limited by the X-ray beam width. Using this X-ray excited luminescence chemical imaging (XELCI) to map pH through porcine tissue, we detected a pH drop during normal bacterial growth on the sensor surface, and a restoration of the pH to the bulk value during antibiotic treatment over the course of hours with millimeter resolution. Overall, XELCI provides a novel approach to noninvasively image surface pH for studying implant infections and treatments.

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Section: Introductionmentioning

confidence: 99%

X‐Ray Excited Luminescence Chemical Imaging of Bacterial Growth on Surfaces Implanted in Tissue

Wang

Raval

Tzeng

et al. 2015

Adv Healthcare Materials

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“…This term captures sensing methods of physical and chemical changes of functionalized surfaces within tissue. An example is described by Chen et al [22] where a phosphor layer was sandwiched in between a thin silver deposit and structural substrate and inserted into pig tissue. X-Ray excited visible phosphor luminescence was adequately transmitted so as to be detected outside the tissue.…”

Section: Introductionmentioning

confidence: 98%

In Vivo X-Ray Imaging of Phosphor-Doped PDMS and Phosphor-Doped Aerogel Biomaterials

Allison

Baker

Lynch

et al. 2015

International Journal of Polymeric Materials and Polymeric Biom

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Non-invasive rapid in vivo imaging and detection of biomedical implants is a critical part of the design and implementation of smart implants. Thermographic phosphors offer a precise and remotely accessible sensing method that has been utilised here. We present the first in vivo X-ray images of La2O2S:Eu-doped crosslinked silica aerogels and polydimethylsiloxane (PDMS) with increasing dopant concentrations. Results show that native PDMS and crosslinked silica aerogel do not show noticeable attenuation of X-rays while image analysis yields values of the absorption coefficient of 0.014 for the doped aerogel and a range of 0.015 to 0.017 for the doped PDMS.

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“…Typical x-ray contrast agents are highly concentrated aqueous solutions (typically iodine-based), and thus cannot be employed for molecular imaging due to their high viscosity and limits on osmolality [5]. To further investigate the molecular imaging potentials for x-ray imaging, x-ray luminescence computed tomography (XLCT) has recently been studied and developed by several groups, including ours [2–4, 6–17]. …”

Section: Introductionmentioning

confidence: 99%

Sensitivity study of x-ray luminescence computed tomography

Lun

Zhang

2017

Appl. Opt.

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X-ray luminescence computed tomography (XLCT) is a hybrid molecular imaging modality that combines the merits of both x-ray imaging (high resolution) and optical imaging (high sensitivity). In this study, we have evaluated the sensitivity of XLCT with phantom experiments by scanning targets of different phosphor concentrations at different depths. We found that XLCT is capable of imaging targets of very low concentrations (27.6 μM or 0.01 mg/mL) at significant depths, such as 21 mm. Our results demonstrate that there is little variation in the reconstructed target size with a maximum target size error of 4.35% for different imaging depths for XLCT. We have for the first time, compared the sensitivity of XLCT with that of traditional computed tomography (CT) for phosphor targets. We found that XLCT’s use of x-ray induced photons provides much higher measurement sensitivity and contrast compared to CT which provides image contrast solely based on x-ray attenuation.

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Optical imaging in tissue with X-ray excited luminescent sensors

Cited by 36 publications

References 43 publications

X‐Ray Excited Luminescence Chemical Imaging of Bacterial Growth on Surfaces Implanted in Tissue

X‐Ray Excited Luminescence Chemical Imaging of Bacterial Growth on Surfaces Implanted in Tissue

In Vivo X-Ray Imaging of Phosphor-Doped PDMS and Phosphor-Doped Aerogel Biomaterials

Sensitivity study of x-ray luminescence computed tomography

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