Review of in vivo optical molecular imaging and sensing from x-ray excitation

Abstract. Significance: Deep-tissue penetration by x-rays to induce optical responses of specific molecular reporters is a new way to sense and image features of tissue function in vivo. Advances in this field are emerging, as biocompatible probes are invented along with innovations in how to optimally utilize x-ray sources. Aim: A comprehensive review is provided of the many tools and techniques developed for x-ray-induced optical molecular sensing, covering topics ranging from foundations of x-ray fluorescence imaging and x-ray tomography to the adaptation of these methods for sensing and imaging in vivo. Approach: The ways in which x-rays can interact with molecules and lead to their optical luminescence are reviewed, including temporal methods based on gated acquisition and multipoint scanning for improved lateral or axial resolution. Results: While some known probes can generate light upon x-ray scintillation, there has been an emergent recognition that excitation of molecular probes by x-ray-induced Cherenkov light is also possible. Emission of Cherenkov radiation requires a threshold energy of x-rays in the high kV or MV range, but has the advantage of being able to excite a broad range of optical molecular probes. In comparison, most scintillating agents are more readily activated by lower keV x-ray energies but are composed of crystalline inorganic constituents, although some organic biocompatible agents have been designed as well. Methods to create high-resolution structured x-ray-optical images are now available, based upon unique scanning approaches and/or a priori knowledge of the scanned x-ray beam geometry. Further improvements in spatial resolution can be achieved by careful system design and algorithm optimization. Current applications of these hybrid x-ray-optical approaches include imaging of tissue oxygenation and pH as well as of certain fluorescent proteins. Conclusions: Discovery of x-ray-excited reporters combined with optimized x-ray scan sequences can improve imaging resolution and sensitivity.

[1]  Michael J. Donzanti,et al.  Shortwave infrared emitting multicolored nanoprobes for biomarker-specific cancer imaging in vivo , 2020, BMC Cancer.

[2]  Brian W. Pogue,et al.  Theoretical lateral and axial sensitivity limits and choices of molecular reporters for Cherenkov-excited luminescence in tissue during x-ray beam scanning , 2020, Journal of biomedical optics.

[3]  Jay V. Shah,et al.  Shortwave Infrared-Emitting Theranostics for Breast Cancer Therapy Response Monitoring , 2020, Frontiers in Molecular Biosciences.

[4]  B. Pogue,et al.  X-ray Induced Cherenkov Optical Triggering of Caged Doxorubicin Released to the Nucleus for Chemoradiation Activation. , 2020, ACS applied materials & interfaces.

[5]  B. Pogue,et al.  Time-gated luminescence imaging for background free in vivo tracking of single circulating tumor cells. , 2020, Optics letters.

[6]  L. Xing,et al.  High‐speed X‐ray‐induced luminescence computed tomography , 2020, Journal of biophotonics.

[7]  L. Xiang,et al.  X-ray Induced Acoustic Computed Tomography for Guiding Prone Stereotactic Partial Breast Irradiation: A Simulation Study. , 2020, Medical physics.

[8]  Brian W. Pogue,et al.  Monte Carlo modeling photon-tissue interaction using on-demand cloud infrastructure , 2020, ArXiv.

[9]  M. Burghammer,et al.  Detection and imaging of gadolinium accumulation in human bone tissue by micro- and submicro-XRF , 2020, Scientific Reports.

[10]  Jennifer R. Shell,et al.  Water-soluble silicon nanocrystals as NIR luminescent probes for time-gated biomedical imaging. , 2020, Nanoscale.

[11]  L. Xiang,et al.  X-ray induced acoustic computed tomography , 2020, Photoacoustics.

[12]  Mengyu Jia,et al.  Tissue pO2 distributions in xenograft tumors dynamically imaged by Cherenkov-excited phosphorescence during fractionated radiation therapy , 2020, Nature Communications.

[13]  Jie Tian,et al.  NIR-II/NIR-I Fluorescence Molecular Tomography of Heterogeneous Mice Based on Gaussian Weighted Neighborhood Fused Lasso Method , 2020, IEEE Transactions on Medical Imaging.

[14]  Junyan Rong,et al.  Limited view cone-beam x-ray luminescence tomography based on depth compensation and group sparsity prior , 2020, Journal of biomedical optics.

[15]  Jennifer R. Shell,et al.  Tumor targeting vitamin B12 derivatives for X-ray induced treatment of pancreatic adenocarcinoma. , 2019, Photodiagnosis and photodynamic therapy.

[16]  Ian F. Harrison,et al.  Imaging of X-Ray-Excited Emissions from Quantum Dots and Biological Tissue in Whole Mouse , 2019, Scientific Reports.

[17]  Qianqian Fang,et al.  Graphics processing unit-accelerated mesh-based Monte Carlo photon transport simulations , 2019, Journal of biomedical optics.

[18]  M. Godlewski,et al.  HfO2:Eu nanoparticles excited by X-rays and UV-visible radiation used in biological imaging , 2019, Journal of Rare Earths.

[19]  D. Manoharan,et al.  Low Dose of X‐Ray‐Excited Long‐Lasting Luminescent Concave Nanocubes in Highly Passive Targeting Deep‐Seated Hepatic Tumors , 2019, Advanced materials.

[20]  L. Xing,et al.  X-ray-induced shortwave infrared luminescence computed tomography. , 2019, Optics letters.

[21]  Caleb J. Behrend,et al.  Noninvasively Imaging pH at the Surface of Implanted Orthopedic Devices with X-ray Excited Luminescence Chemical Imaging. , 2019, ACS sensors.

[22]  Yoichi Watanabe,et al.  Space-variant deconvolution of Cerenkov light images acquired from a curved surface. , 2019, Medical physics.

[23]  Tanner Young-Schultz,et al.  FullMonteCUDA: a fast, flexible, and accurate GPU-accelerated Monte Carlo simulator for light propagation in turbid media. , 2019, Biomedical optics express.

[24]  Juan Li,et al.  X-ray Nanocrystal Scintillator-based Aptasensor for Autofluorescence-free Detection. , 2019, Analytical chemistry.

[25]  B. Pogue,et al.  Cherenkov-excited luminescence scanned imaging using scanned beam differencing and iterative deconvolution in dynamic plan radiation delivery in a human breast phantom geometry. , 2019, Medical physics.

[26]  Yanmin Yang,et al.  Efficient X-ray excited short-wavelength infrared phosphor. , 2019, Optics express.

[27]  B. Pogue,et al.  Tomographic Cherenkov-excited luminescence scanned imaging with multiple pinhole beams recovered via back-projection reconstruction. , 2019, Optics letters.

[28]  Xu Cao,et al.  Characterizing short-wave infrared fluorescence of conventional near-infrared fluorophores , 2019, Journal of biomedical optics.

[29]  Mark S. Bolding,et al.  Organic Fluorophore Coated Polycrystalline Ceramic LSO:Ce Scintillators for X-ray Bioimaging. , 2018, Langmuir : the ACS journal of surfaces and colloids.

[30]  Junyan Rong,et al.  Regularized reconstruction based on joint L1 and total variation for sparse-view cone-beam X-ray luminescence computed tomography. , 2018, Biomedical optics express.

[31]  C. Moriyoshi,et al.  X-ray-activated long persistent phosphors featuring strong UVC afterglow emissions , 2018, Light, science & applications.

[32]  Xu Cao,et al.  Cherenkov excited short-wavelength infrared fluorescence imaging in vivo with external beam radiation , 2018, Journal of biomedical optics.

[33]  Yoichi Watanabe,et al.  Characterization of the Cerenkov scatter function: a convolution kernel for Cerenkov light dosimetry , 2018, Journal of biomedical optics.

[34]  B. Pogue,et al.  Multi-beam scan analysis with a clinical LINAC for high resolution Cherenkov-excited molecular luminescence imaging in tissue , 2018, Biomedical optics express.

[35]  B. Pogue,et al.  Observation of short wavelength infrared (SWIR) Cherenkov emission. , 2018, Optics letters.

[36]  Xiaobin Tang,et al.  Analysis on the emission and potential application of Cherenkov radiation in boron neutron capture therapy: A Monte Carlo simulation study. , 2018, Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine.

[37]  Yoichi Watanabe,et al.  A mathematical deconvolution formulation for superficial dose distribution measurement by Cerenkov light dosimetry , 2018, Medical physics.

[38]  J. Mohapatra,et al.  X-ray excited luminescence and persistent luminescence of Sr2MgSi2O7:Eu2+, Dy3+ and their associations with synthesis conditions , 2018, Journal of Luminescence.

[39]  Huanghao Yang,et al.  Autofluorescence-Free Immunoassay Using X-ray Scintillating Nanotags. , 2018, Analytical chemistry.

[40]  Jennifer R. Shell,et al.  Maps of in vivo oxygen pressure with submillimetre resolution and nanomolar sensitivity enabled by Cherenkov-excited luminescence scanned imaging , 2018, Nature Biomedical Engineering.

[41]  C. A. Chang,et al.  Lanthanide-Doped Core-Shell-Shell Nanocomposite for Dual Photodynamic Therapy and Luminescence Imaging by a Single X-ray Excitation Source. , 2018, ACS applied materials & interfaces.

[42]  Huang-Hao Yang,et al.  High-efficiency X-ray luminescence in Eu3+-activated tungstate nanoprobes for optical imaging through energy transfer sensitization. , 2018, Nanoscale.

[43]  Brian W Pogue,et al.  Cherenkov-excited Multi-Fluorophore Sensing in Tissue-Simulating Phantoms and In Vivo from External Beam Radiotherapy , 2017, Radiation Research.

[44]  T. Ishikawa,et al.  Ellipsoidal mirror for two-dimensional 100-nm focusing in hard X-ray region , 2017, Scientific Reports.

[45]  Saša Bajt,et al.  X-ray focusing with efficient high-NA multilayer Laue lenses , 2017, Light: Science & Applications.

[46]  A. Knijnenberg,et al.  Large area imaging of forensic evidence with MA-XRF , 2017, Scientific Reports.

[47]  Hongbing Lu,et al.  Sub-10 nm Water-Dispersible β-NaGdF4:X% Eu3+ Nanoparticles with Enhanced Biocompatibility for in Vivo X-ray Luminescence Computed Tomography. , 2017, ACS applied materials & interfaces.

[48]  Huangjian Yi,et al.  Combined multi-spectrum and orthogonal Laplacianfaces for fast CB-XLCT imaging with single-view data , 2017 .

[49]  Byeong-Cheol Ahn,et al.  Molecular Imaging: A Useful Tool for the Development of Natural Killer Cell-Based Immunotherapies , 2017, Front. Immunol..

[50]  Gregory Palmer,et al.  Noninvasive measurement of tissue blood oxygenation with Cerenkov imaging during therapeutic radiation delivery. , 2017, Optics letters.

[51]  Jianhua Hao,et al.  X-ray-Activated Near-Infrared Persistent Luminescent Probe for Deep-Tissue and Renewable in Vivo Bioimaging. , 2017, ACS applied materials & interfaces.

[52]  S. W. Allison,et al.  In vivo X-Ray excited optical luminescence from phosphor-doped aerogel and Sylgard 184 composites , 2017 .

[53]  E. Goldys,et al.  Light-Triggerable Liposomes for Enhanced Endolysosomal Escape and Gene Silencing in PC12 Cells , 2017, Molecular therapy. Nucleic acids.

[54]  Wei Zhang,et al.  Sensitivity study of x-ray luminescence computed tomography. , 2017, Applied optics.

[55]  R. Decréau,et al.  Redshifted Cherenkov Radiation for in vivo Imaging: Coupling Cherenkov Radiation Energy Transfer to multiple Förster Resonance Energy Transfers , 2017, Scientific Reports.

[56]  Bob Nagler,et al.  Perfect X-ray focusing via fitting corrective glasses to aberrated optics , 2017, Nature Communications.

[57]  Juan Li,et al.  Repeatable deep-tissue activation of persistent luminescent nanoparticles by soft X-ray for high sensitivity long-term in vivo bioimaging. , 2017, Nanoscale.

[58]  Pierre Léger,et al.  Experimental evaluation of x‐ray acoustic computed tomography for radiotherapy dosimetry applications , 2017, Medical physics.

[59]  Fanzhen Meng,et al.  Cone Beam X-Ray Luminescence Tomography Imaging Based on KA-FEM Method for Small Animals , 2016, BioMed research international.

[60]  Jinchao Feng,et al.  Multiobjective guided priors improve the accuracy of near-infrared spectral tomography for breast imaging. , 2016, Journal of biomedical optics.

[61]  Joe Y. Chang,et al.  Immunotherapy and stereotactic ablative radiotherapy (ISABR): a curative approach? , 2016, Nature Reviews Clinical Oncology.

[62]  B. Pogue,et al.  Light sheet luminescence imaging with Cherenkov excitation in thick scattering media. , 2016, Optics letters.

[63]  Lei Xing,et al.  High Resolution X-ray-Induced Acoustic Tomography , 2016, Scientific Reports.

[64]  Xunbin Wei,et al.  eEF1A1 binds and enriches protoporphyrin IX in cancer cells in 5-aminolevulinic acid based photodynamic therapy , 2016, Scientific Reports.

[65]  Brian W Pogue,et al.  Comparison of Cherenkov excited fluorescence and phosphorescence molecular sensing from tissue with external beam irradiation , 2016, Physics in medicine and biology.

[66]  Emily A. Smith,et al.  What Is the Best Method to Fit Time-Resolved Data? A Comparison of the Residual Minimization and the Maximum Likelihood Techniques As Applied to Experimental Time-Correlated, Single-Photon Counting Data. , 2016, The journal of physical chemistry. B.

[67]  Rongxiao Zhang,et al.  Cherenkov radiation fluence estimates in tissue for molecular imaging and therapy applications , 2015, SPIE BiOS.

[68]  M. Bissonnette,et al.  X-Ray Fluorescence Microscopy Demonstrates Preferential Accumulation of a Vanadium-Based Magnetic Resonance Imaging Contrast Agent in Murine Colonic Tumors , 2015, Molecular imaging.

[69]  Y. Raval,et al.  X‐Ray Excited Luminescence Chemical Imaging of Bacterial Growth on Surfaces Implanted in Tissue , 2015, Advanced healthcare materials.

[70]  Feng Liu,et al.  Nanoscintillator-mediated X-ray inducible photodynamic therapy for in vivo cancer treatment. , 2015, Nano letters.

[71]  Brian W Pogue,et al.  Cherenkov-excited luminescence scanned imaging. , 2015, Optics letters.

[72]  Samuel Achilefu,et al.  Breaking the Depth Dependency of Phototherapy with Cerenkov Radiation and Low Radiance Responsive Nanophotosensitizers , 2015, Nature nanotechnology.

[73]  A. Beale,et al.  Chemical imaging of single catalyst particles with scanning μ-XANES-CT and μ-XRF-CT. , 2015, Physical chemistry chemical physics : PCCP.

[74]  Lukman Thalib,et al.  Efficacy of localized phototherapy and photodynamic therapy for psoriasis: a systematic review and meta‐analysis , 2015, Photodermatology, photoimmunology & photomedicine.

[75]  Petras Juzenas,et al.  X-ray-induced nanoparticle-based photodynamic therapy of cancer. , 2014, Nanomedicine.

[76]  Shouping Zhu,et al.  Quantitative cone beam X-ray luminescence tomography/X-ray computed tomography imaging , 2014 .

[77]  Sergei A. Vinogradov,et al.  Cherenkov excited phosphorescence-based pO2 estimation during multi-beam radiation therapy: phantom and simulation studies , 2014, Physics in medicine and biology.

[78]  M. Hackett,et al.  Elemental and Chemically Specific X-ray Fluorescence Imaging of Biological Systems , 2014, Chemical reviews.

[79]  Brian W Pogue,et al.  Optical dosimetry of radiotherapy beams using Cherenkov radiation: the relationship between light emission and dose , 2014, Physics in medicine and biology.

[80]  Ge Wang,et al.  X-ray micromodulated luminescence tomography in dual-cone geometry , 2014, Journal of biomedical optics.

[81]  P. Dorenbos,et al.  High Light Yield of Sr8(Si4O12)Cl8:Eu2+ under X-ray Excitation and Its Temperature-Dependent Luminescence Characteristics , 2014 .

[82]  Lei Xing,et al.  Synergistic Assembly of Heavy Metal Clusters and Luminescent Organic Bridging Ligands in Metal–Organic Frameworks for Highly Efficient X-ray Scintillation , 2014, Journal of the American Chemical Society.

[83]  Simon R Cherry,et al.  Numerical simulation of x-ray luminescence optical tomography for small-animal imaging , 2014, Journal of biomedical optics.

[84]  Lei Xing,et al.  Hard X-ray-induced optical luminescence via biomolecule-directed metal clusters. , 2014, Chemical communications.

[85]  Ian M. Kennedy,et al.  NaGdF4:Eu3+ Nanoparticles for Enhanced X-ray Excited Optical Imaging , 2014, Chemistry of materials : a publication of the American Chemical Society.

[86]  Jianwen Luo,et al.  A Direct Method With Structural Priors for Imaging Pharmacokinetic Parameters in Dynamic Fluorescence Molecular Tomography , 2014, IEEE Transactions on Biomedical Engineering.

[87]  Qimei Liao,et al.  In vivo x-ray luminescence tomographic imaging with single-view data. , 2013, Optics letters.

[88]  Julien Bec,et al.  X-ray luminescence optical tomography imaging: experimental studies. , 2013, Optics letters.

[89]  Scott C Davis,et al.  Oxygen tomography by Čerenkov-excited phosphorescence during external beam irradiation , 2013, Journal of biomedical optics.

[90]  Brian W. Pogue,et al.  A GAMOS plug-in for GEANT4 based Monte Carlo simulation of radiation-induced light transport in biological media , 2013, Biomedical optics express.

[91]  Lei Xing,et al.  First Demonstration of Multiplexed X-Ray Fluorescence Computed Tomography (XFCT) Imaging , 2013, IEEE Transactions on Medical Imaging.

[92]  Jianwen Luo,et al.  MAP estimation with structural priors for fluorescence molecular tomography , 2013, Physics in medicine and biology.

[93]  John C. Gore,et al.  Monitoring pH-triggered drug release from radioluminescent nanocapsules with X-ray excited optical luminescence. , 2013, ACS nano.

[94]  Lei Xing,et al.  X-ray acoustic computed tomography with pulsed x-ray beam from a medical linear accelerator. , 2012, Medical physics.

[95]  Wei Chen,et al.  Solution combustion synthesis, photoluminescence and X-ray luminescence of Eu-doped nanoceria CeO2:Eu , 2012 .

[96]  Lei Xing,et al.  Investigation of X-ray Fluorescence Computed Tomography (XFCT) and K-Edge Imaging , 2012, IEEE Transactions on Medical Imaging.

[97]  A. Armstrong,et al.  Combination treatments for psoriasis: a systematic review and meta-analysis. , 2012, Archives of dermatology.

[98]  Scott C Davis,et al.  Time-gated Cherenkov emission spectroscopy from linear accelerator irradiation of tissue phantoms. , 2012, Optics letters.

[99]  S. Feldman,et al.  A review of targeted ultraviolet B phototherapy for psoriasis. , 2012, Journal of the American Academy of Dermatology.

[100]  J. Hesser,et al.  GMC: a GPU implementation of a Monte Carlo dose calculation based on Geant4 , 2012, Physics in medicine and biology.

[101]  Brian W. Pogue,et al.  Quantitative Cherenkov emission spectroscopy for tissue oxygenation assessment , 2012, Optics express.

[102]  Guillem Pratx,et al.  Fully 3D list-mode time-of-flight PET image reconstruction on GPUs using CUDA. , 2011, Medical physics.

[103]  Lei Xing,et al.  Ultrafast and scalable cone-beam CT reconstruction using MapReduce in a cloud computing environment. , 2011, Medical physics.

[104]  Claudiu T. Supuran,et al.  Interfering with pH regulation in tumours as a therapeutic strategy , 2011, Nature Reviews Drug Discovery.

[105]  L Xing,et al.  Limited-angle x-ray luminescence tomography: methodology and feasibility study , 2011, Physics in medicine and biology.

[106]  Zhiqiang Yang,et al.  High-resolution chemical imaging through tissue with an X-ray scintillator sensor. , 2011, Analytical chemistry.

[107]  David Kessel,et al.  Photodynamic therapy of cancer: An update , 2011, CA: a cancer journal for clinicians.

[108]  Michael Landthaler,et al.  2D luminescence imaging of pH in vivo , 2011, Proceedings of the National Academy of Sciences.

[109]  Brian W. Pogue,et al.  Singular value decomposition metrics show limitations of detector design in diffuse fluorescence tomography , 2010, Biomedical optics express.

[110]  Lei Xing,et al.  Tomographic molecular imaging of x-ray-excitable nanoparticles. , 2010, Optics letters.

[111]  Erin Jackson,et al.  Cerenkov Radiation Energy Transfer (CRET) Imaging: A Novel Method for Optical Imaging of PET Isotopes in Biological Systems , 2010, PloS one.

[112]  Terence S Leung,et al.  Fast Monte Carlo simulations of ultrasound-modulated light using a graphics processing unit. , 2010, Journal of biomedical optics.

[113]  L Xing,et al.  Hybrid x-ray/optical luminescence imaging: characterization of experimental conditions. , 2010, Medical physics.

[114]  Lei Xing,et al.  X-Ray Luminescence Computed Tomography via Selective Excitation: A Feasibility Study , 2010, IEEE Transactions on Medical Imaging.

[115]  C. Thiam,et al.  Simulation of Cherenkov photons emitted in photomultiplier windows induced by Compton diffusion using the Monte Carlo code GEANT4. , 2010, Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine.

[116]  Vasilis Ntziachristos,et al.  Imaging performance of a hybrid x-ray computed tomography-fluorescence molecular tomography system using priors. , 2010, Medical physics.

[117]  F. Liu,et al.  X-ray fluorescence computed tomography (XFCT) imaging of gold nanoparticle-loaded objects using 110 kVp x-rays , 2010, Physics in medicine and biology.

[118]  Scott C Davis,et al.  Pre-clinical whole-body fluorescence imaging: Review of instruments, methods and applications. , 2010, Journal of photochemistry and photobiology. B, Biology.

[119]  P. Yepes,et al.  Intercomparision of Monte Carlo Radiation Transport Codes MCNPX, GEANT4, and FLUKA for Simulating Proton Radiotherapy of the Eye , 2009, Nuclear technology.

[120]  P. J. La Riviere,et al.  Accelerating X-ray fluorescence computed tomography , 2009, 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[121]  David A Boas,et al.  Monte Carlo simulation of photon migration in 3D turbid media accelerated by graphics processing units. , 2009, Optics express.

[122]  Paola Taroni,et al.  Time-Resolved Diffuse Optical Spectroscopy: A Differential Absorption Approach , 2009, European Conference on Biomedical Optics.

[123]  R. Leahy,et al.  A three-dimensional multispectral fluorescence optical tomography imaging system for small animals based on a conical mirror design. , 2009, Optics express.

[124]  H. Daldrup-Link,et al.  Optical Imaging of Cellular Immunotherapy against Prostate Cancer , 2009, Molecular imaging.

[125]  Shi Ke,et al.  In vivo fluorescent optical imaging of cytotoxic T lymphocyte migration using IRDye800CW near-infrared dye. , 2008, Applied optics.

[126]  Wei Yang,et al.  Spatial Weighed Element Based FEM Incorporating a Priori Information on Bioluminescence Tomography , 2008, MICCAI.

[127]  T. Sham,et al.  Origin of Luminescence from Silicon Nanocrystals: a Near Edge X-ray Absorption Fine Structure (NEXAFS) and X-ray Excited Optical Luminescence (XEOL) Study of Oxide-Embedded and Free-Standing Systems , 2008 .

[128]  B. Wilson,et al.  The physics, biophysics and technology of photodynamic therapy , 2008, Physics in medicine and biology.

[129]  S. L. Westcott,et al.  X-ray luminescence of LaF3:Tb3+ and LaF3: Ce3+,Tb3+ water-soluble nanoparticles , 2008 .

[130]  M. Ericson,et al.  Review of photodynamic therapy in actinic keratosis and basal cell carcinoma , 2008, Therapeutics and clinical risk management.

[131]  R. Weissleder,et al.  A Near-Infrared Cell Tracker Reagent for Multiscopic In Vivo Imaging and Quantification of Leukocyte Immune Responses , 2007, PloS one.

[132]  Mark W. Dewhirst,et al.  Hypoxia and radiotherapy: opportunities for improved outcomes in cancer treatment , 2007, Cancer and Metastasis Reviews.

[133]  Wei Chen,et al.  Using nanoparticles to enable simultaneous radiation and photodynamic therapies for cancer treatment. , 2006, Journal of nanoscience and nanotechnology.

[134]  J. Williams,et al.  Synthesis and pH-sensitive luminescence of bis-terpyridyl iridium(III) complexes incorporating pendent pyridyl groups , 2006 .

[135]  B. Pogue,et al.  Spectrally resolved bioluminescence optical tomography. , 2006, Optics letters.

[136]  J. Carruthers,et al.  The use of photodynamic therapy in dermatology: results of a consensus conference. , 2006, Journal of drugs in dermatology : JDD.

[137]  B. Pogue,et al.  Spectral priors improve near-infrared diffuse tomography more than spatial priors. , 2005, Optics letters.

[138]  Zheng Huang,et al.  A Review of Progress in Clinical Photodynamic Therapy , 2005, Technology in cancer research & treatment.

[139]  E. Miller,et al.  Optimal linear inverse solution with multiple priors in diffuse optical tomography. , 2005, Applied optics.

[140]  H Paganetti,et al.  Adaptation of GEANT4 to Monte Carlo dose calculations based on CT data. , 2004, Medical physics.

[141]  S. Durham,et al.  Mechanisms of immunotherapy. , 2004, The Journal of allergy and clinical immunology.

[142]  H. Barr,et al.  The potential role for photodynamic therapy in the management of upper gastrointestinal disease , 2001, Alimentary pharmacology & therapeutics.

[143]  M. Nikl Wide Band Gap Scintillation Materials: Progress in the Technology and Material Understanding , 2000 .

[144]  M. Dewhirst,et al.  Oxygenation of head and neck cancer: changes during radiotherapy and impact on treatment outcome. , 1999, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[145]  P. P. Pasker-De Jong,et al.  Treatment with UV-B for psoriasis and nonmelanoma skin cancer: a systematic review of the literature. , 1999, Archives of dermatology.

[146]  J L Bedford,et al.  Comparison of a multi-leaf collimator with conformal blocks for the delivery of stereotactically guided conformal radiotherapy. , 1999, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[147]  Harry A. Schmitt,et al.  Pulsed radiography for detection of corrosion on shrink wrapped shipboard electrical connectors , 1996 .

[148]  S. Mattsson,et al.  Toxicology; in vivo x-ray fluorescence for the assessment of heavy metal concentrations in man. , 1995, Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine.

[149]  J M Wilkinson,et al.  Computer-assisted generation of multi-leaf collimator settings for conformation therapy. , 1992, The British journal of radiology.

[150]  T. Delaney,et al.  Photodynamic therapy of cancer. , 1988, Comprehensive therapy.

[151]  M S Patterson,et al.  The physics of photodynamic therapy. , 1986, Physics in medicine and biology.

[152]  S. Brown,et al.  Cerenkov radiation and its applications , 1955 .

[153]  Z. Xu,et al.  X-ray fluorescence imaging of metals and metalloids in biological systems. , 2018, American journal of nuclear medicine and molecular imaging.

[154]  S. R. Wiegell Update on photodynamic treatment for actinic keratosis. , 2015, Current problems in dermatology.

[155]  Bert Masschaele,et al.  Three-dimensional elemental imaging by means of synchrotron radiation micro-XRF: developments and applications in environmental chemistry , 2008, Analytical and bioanalytical chemistry.

[156]  B. Pogue,et al.  Targeted optical imaging and photodynamic therapy. , 2005, Ernst Schering Research Foundation workshop.

[157]  K. König,et al.  Fluorescence lifetime imaging by time‐correlated single‐photon counting , 2004, Microscopy research and technique.

[158]  J. Williams,et al.  Iridium(III) bis-terpyridine complexes displaying long-lived pH sensitive luminescence , 1999 .

[159]  P. Vaupel,et al.  Hypoxia and Radiation Response in Human Tumors. , 1996, Seminars in radiation oncology.

[160]  M. Prasad,et al.  Trace elemental analysis of extracted dust from lungs and lymph nodes of domestic animals using X-ray fluorescence technique. , 1980, International journal of environmental analytical chemistry.