Showing total 50 results

1. Review of successful pathways for regulatory approvals in open-field fluorescence-guided surgery

Author

Eben L. Rosenthal and Brian W. Pogue

Subjects

Paper, Indocyanine Green, medicine.medical_specialty, fluorescein, Computer science, Biomedical Engineering, Contrast Media, Fluorescent imaging, Subspecialty, 01 natural sciences, perfusion, Fluorescence, 010309 optics, Biomaterials, Food and drug administration, surgical, 0103 physical sciences, Premarket Approval, medicine, cancer, Humans, Review Papers, Fluorescent Dyes, United States Food and Drug Administration, Fluorescence angiography, Open surgery, contrast, United States, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Surgery, Retinal imaging, Clearance

Abstract

Significance: The modern use of fluorescence in surgery came iteratively through new devices and pre-existing imaging agents, with indications that were paved via regulatory approvals and device clearances. These events led to a growing set of surgery subspecialty uses. Aim: This article outlines the key milestones that initiated commercially marketed systems and agents by highlighting temporal sequences and strategic decisions between them, with the goal of helping to inform future successes. Approach: A review of successful regulatory approvals and the sequences between them was completed for companies that achieved US Food and Drug Administration (FDA) premarket approval or new drug approvals (NDAs) or device clearances in the fields of fluorescent imaging agents, open surgery imaging devices, and their approved medical indications. Results: Angiography agents, indocyanine green and fluorescein, were approved for human use as absorbing dyes, and this use in retinal imaging was the precursor to lateral translation into tissue perfusion imaging in the last two decades with a growing number of devices. Many FDA cleared devices for open fluorescence-guided surgery used the predicate created by the SPY SP2000 system. This first system was 510(k) cleared for angiography imaging with a unique split predicate from x-ray imaging of vasculature and retinal fluorescence angiography. Since that time, the lateral spread of open surgery devices being cleared for new indications has been occurring with a growth of adoption in surgical subspecialties. Growth into new surgical subspecialties has been achieved by leveraging different NDAs and clearances between indications, such that medical uses have broadened over time. Conclusions: Key decisions made by developers to advance specific device clearances and NDAs have been based upon existing optical fluorescent agents. The historical lessons and regulatory trends in newer indications and contrast agents can help the field evolve via successful investment in new systems and applications.

Published

2021

2. Indocyanine green matching phantom for fluorescence-guided surgery imaging system characterization and performance assessment

Author

Dimitris Gorpas, Vasilis Ntziachristos, Alberto J. Ruiz, Ethan P. M. LaRochelle, Brian W. Pogue, T. Joshua Pfefer, and Mindy Wu

Subjects

Indocyanine Green, Paper, Fluorescence-lifetime imaging microscopy, medicine.medical_specialty, Matching (statistics), Computer science, Biomedical Engineering, Fluorescence-guided Surgery, Imaging Standard, Surgery, Tissue Simulating Phantoms, 01 natural sciences, Imaging phantom, Imaging, 010309 optics, Biomaterials, surgery, chemistry.chemical_compound, tissue simulating phantoms, 0103 physical sciences, medicine, Sensitivity (control systems), Image resolution, imaging standard, Phantoms, Imaging, Optical Imaging, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Characterization (materials science), chemistry, Benchmark (computing), Indocyanine green, fluorescence-guided surgery

Abstract

Significance: Expanded use of fluorescence-guided surgery with devices approved for use with indocyanine green (ICG) has led to a range of commercial systems available. There is a compelling need to be able to independently characterize system performance and allow for cross-system comparisons. Aim: The goal of this work is to expand on previous proposed fluorescence imaging standard designs to develop a long-term stable phantom that spectrally matches ICG characteristics and utilizes 3D printing technology for incorporating tissue-equivalent materials. Approach: A batch of test targets was created to assess ICG concentration sensitivity in the 0.3- to 1000-nM range, tissue-equivalent depth sensitivity down to 6 mm, and spatial resolution with a USAF test chart. Comparisons were completed with a range of systems that have significantly different imaging capabilities and applications, including the Li-Cor® Odyssey, Li-Cor® Pearl, PerkinElmer® Solaris, and Stryker® Spy Elite. Results: Imaging of the ICG-matching phantoms with all four commercially available systems showed the ability to benchmark system performance and allow for cross-system comparisons. The fluorescence tests were able to assess differences in the detectable concentrations of ICG with sensitivity differences >10× for preclinical and clinical systems. Furthermore, the tests successfully assessed system differences in the depth-signal decay rate, as well as resolution performance and image artifacts. The manufacturing variations, photostability, and mechanical design of the tests showed promise in providing long-term stable standards for fluorescence imaging. Conclusions: The presented ICG-matching phantom provides a major step toward standardizing performance characterization and cross-system comparisons for devices approved for use with ICG. The developed hybrid manufacturing platform can incorporate long-term stable fluorescing agents with 3D printed tissue-equivalent material. Further, long-term testing of the phantom and refinements to the manufacturing process are necessary for future implementation as a widely adopted fluorescence imaging standard.

Published

2020

3. Intracranial glioma xenograft model rapidly reestablishes blood–brain barrier integrity for longitudinal imaging of tumor progression using fluorescence molecular tomography and contrast agents

Author

Gail Sudlow, Hong Chen, Le Moyne Habimana-Griffin, Lynne Marsala, Joshua B. Rubin, Matthew Mixdorf, Dezhuang Ye, Julia Carpenter, Samuel Achilefu, and Julie L. Prior

Subjects

Paper, Indocyanine Green, Near-Infrared Fluorescence Imaging, Pathology, medicine.medical_specialty, longitudinal imaging, Green Fluorescent Proteins, Transplantation, Heterologous, Biomedical Engineering, Brain tumor, Contrast Media, Mice, Nude, Blood–brain barrier, 01 natural sciences, Imaging, 010309 optics, Biomaterials, near-infrared fluorescence imaging, Mice, Glioma, 0103 physical sciences, medicine, Image Processing, Computer-Assisted, Bioluminescence imaging, Animals, Tomography, Optical, fluorescence molecular tomography, Coloring Agents, Luminescent Agents, business.industry, Brain Neoplasms, glioblastoma, medicine.disease, molecular imaging, Atomic and Molecular Physics, and Optics, 3. Good health, Electronic, Optical and Magnetic Materials, Disease Models, Animal, medicine.anatomical_structure, Microscopy, Fluorescence, Tumor progression, Blood-Brain Barrier, Stereotactic injection, focused ultrasound, Female, Molecular imaging, business, Neoplasm Transplantation

Abstract

Significance: The blood–brain barrier (BBB) is a major obstacle to detecting and treating brain tumors. Overcoming this challenge will facilitate the early and accurate detection of brain lesions and guide surgical resection of tumors. Aim: We generated an orthotopic brain tumor model that simulates the pathophysiology of gliomas at early stages; determine the BBB integrity and breakdown over the time course of tumor progression using generic and cancer-targeted near-infrared (NIR) fluorescent molecular probes. Approach: We developed an intracranial tumor xenograft model that rapidly reestablished BBB integrity and monitored tumor progression by bioluminescence imaging. Sham control mice were injected with phosphate-buffered saline only. Fluorescence molecular tomography (FMT) was used to quantify the uptake of tumor-targeted and passive NIR fluorescent imaging agents in orthotopic glioma (U87-GL-GFP PDE7B H217Q cells) tumor model. Cancer-induced and transient (with focused ultrasound, FUS) disruption of BBB integrity was monitored with NIR fluorescent dyes. Results: Stereotactic injection of 50,000 cells into mouse brain allowed rapid reestablishment of BBB integrity within a week, as determined by the inability of both tumor-targeted and generic NIR imaging agents to extravasate into the brain. Tumor-induced BBB disruption was observed 7 weeks after tumor implantation. FUS achieved a similar effect at any time point after reestablishing BBB integrity. While tumor uptake and retention of the passive NIR dye, indocyanine green, was negligible, both actively tumor-targeting agents exhibited selective accumulation in the tumor region. The tumor-targeting molecular probe that clears rapidly from nontumor brain tissue exhibits higher contrast than the analogous vascular-targeting agent and helps delineate tumors from sham control. Conclusions: We highlight the utility of FMT imaging for longitudinal assessment of brain tumors and the interplay between the stages of BBB disruption and molecular probe retention in tumors, with potential application to other neurological diseases.

Published

2020

4. Intraoperative fluorescence perfusion assessment should be corrected by a measured subject-specific arterial input function

Author

Brian W. Pogue, Rocco R. Addante, Gerard-Paul Slobegean, Shudong Jiang, Ida Leah Gitajn, Eric Henderson, and Jonathan T. Elliott

Subjects

Paper, Fluorescence-lifetime imaging microscopy, indocyanine green, Materials science, Biomedical Engineering, Contrast Media, 01 natural sciences, perfusion, Imaging, 010309 optics, Biomaterials, chemistry.chemical_compound, In vivo, 0103 physical sciences, Humans, angiography, Pulse (signal processing), Homogeneity (statistics), Reproducibility of Results, Arteries, Magnetic Resonance Imaging, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Intensity (physics), chemistry, arterial input function, tracer kinetics, fluorescence, Densitometry, Indocyanine green, Perfusion, Algorithms, Biomedical engineering

Abstract

Significance: The effects of varying the indocyanine green injection dose, injection rate, physiologic dispersion of dye, and intravenous tubing volume propagate into the shape and magnitude of the arterial input function (AIF) during intraoperative fluorescence perfusion assessment, thereby altering the observed kinetics of the fluorescence images in vivo. Aim: Numerical simulations are used to demonstrate the effect of AIF on metrics derived from tissue concentration curves such as peak fluorescence, time-to-peak (TTP), and egress slope. Approach: Forward models of tissue concentration were produced by convolving simulated AIFs with the adiabatic approximation to the tissue homogeneity model using input parameters representing six different tissue examples (normal brain, glioma, normal skin, ischemic skin, normal bone, and osteonecrosis). Results: The results show that AIF perturbations result in variations in estimates of total intensity of up to 80% and TTP error of up to 200%, with the errors more dominant in brain, less in skin, and less in bone. Interestingly, error in ingress slope was as high as 60% across all tissue types. These are key observable parameters used in fluorescence imaging either implicitly by viewing the image or explicitly through intensity fitting algorithms. Correcting by deconvolving the image with a measured subject-specific AIF provides an intuitive means of visualizing the data while also removing the source of variance and allowing intra- and intersubject comparisons. Conclusions: These results suggest that intraoperative fluorescence perfusion assessment should be corrected by patient-specific AIFs measured by pulse dye densitometry.

Published

2020

5. Perspective review of what is needed for molecular-specific fluorescence-guided surgery

Author

Gooitzen M. van Dam, Brian W. Pogue, Eben L. Rosenthal, and Samuel Achilefu

Subjects

Paper, medicine.medical_specialty, Computer science, Microdosing, CLINICAL-APPLICATIONS, Biomedical Engineering, INDOCYANINE GREEN, BLADDER-CANCER, 5-AMINOLEVULINIC ACID, 030218 nuclear medicine & medical imaging, Biomaterials, Mice, 03 medical and health sciences, 0302 clinical medicine, surgical, NECK-CANCER, Neoplasms, medicine, Animals, Humans, cancer, resection, IN-VIVO, Fluorodeoxyglucose, therapy, fluorescent, medicine.diagnostic_test, IMAGING TECHNOLOGIES, Molecular pathology, Optical Imaging, Perspective (graphical), Atomic and Molecular Physics, and Optics, Molecular Imaging, 3. Good health, Electronic, Optical and Magnetic Materials, Surgery, Specific fluorescence, Workflow, Surgery, Computer-Assisted, Positron emission tomography, GLIOMA SURGERY, 030220 oncology & carcinogenesis, MEDIATED PHOTODYNAMIC DIAGNOSIS, ONCOLOGIC SURGERY, Preclinical imaging, Perspectives, medicine.drug

Abstract

Molecular image-guided surgery has the potential for translating the tools of molecular pathology to real-time guidance in surgery. As a whole, there are incredibly positive indicators of growth, including the first United States Food and Drug Administration clearance of an enzyme-biosynthetic-activated probe for surgery guidance, and a growing number of companies producing agents and imaging systems. The strengths and opportunities must be continued but are hampered by important weaknesses and threats within the field. A key issue to solve is the inability of macroscopic imaging tools to resolve microscopic biological disease heterogeneity and the limitations in microscopic systems matching surgery workflow. A related issue is that parsing out true molecular-specific uptake from simple-enhanced permeability and retention is hard and requires extensive pathologic analysis or multiple in vivo tests, comparing fluorescence accumulation with standard histopathology and immunohistochemistry. A related concern in the field is the over-reliance on a finite number of chosen preclinical models, leading to early clinical translation when the probe might not be optimized for high intertumor variation or intratumor heterogeneity. The ultimate potential may require multiple probes, as are used in molecular pathology, and a combination with ultrahigh-resolution imaging and image recognition systems, which capture the data at a finer granularity than is possible by the surgeon. Alternatively, one might choose a more generalized approach by developing the tracer based on generic hallmarks of cancer to create a more "one-size-fits-all" concept, similar to metabolic aberrations as exploited in fluorodeoxyglucose-positron emission tomography (FDG-PET) (i.e., Warburg effect) or tumor acidity. Finally, methods to approach the problem of production cost minimization and regulatory approvals in a manner consistent with the potential revenue of the field will be important. In this area, some solid steps have been demonstrated in the use of fluorescent labeling commercial antibodies and separately in microdosing studies with small molecules. (C) The Authors.

Published

2018

6. Characterization and validation of multimodal annihilation-gamma/near-infrared/visible laparoscopic system

Author

Seong Hyun Song, Young Been Han, Dae Hong Jeong, Soo Mee Kim, Seong Jong Hong, Ho-Young Lee, and Han Gyu Kang

Subjects

Paper, Indocyanine Green, Fluorescence-lifetime imaging microscopy, positron emission tomography, Materials science, Photon, Biomedical Engineering, Multimodal Imaging, 01 natural sciences, Imaging, 010309 optics, Biomaterials, Optics, fluorescence imaging, Robotic Surgical Procedures, 0103 physical sciences, medicine, minimally invasive robotic surgery, Penetration depth, Spectroscopy, Near-Infrared, medicine.diagnostic_test, Phantoms, Imaging, business.industry, Near-infrared spectroscopy, Detector, multimodal imaging system, Gamma ray, Signal Processing, Computer-Assisted, Equipment Design, equipment and supplies, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Positron emission tomography, Laparoscopy, business, Visible spectrum

Abstract

Minimally invasive robotic surgery using fluorescence-guided images with a video laparoscope has been widely used because of its advantages of small incision, fast recovery time, and efficiency. However, the penetration depth limitation of fluorescence is a disadvantage caused by the absorption and scattering in tissues and blood cells. If this limitation can be overcome by additional imaging modalities, the surgical procedure can be quite efficient and precise. High-energy annihilation-gamma photons have a stronger penetration capability than visible and fluorescence photons. To characterize and validate a multimodal annihilation-gamma/near-infrared (NIR)/visible laparoscopic imaging system, an internal detector composed of an annihilation-gamma detector and an optical system was assembled inside a surgical stainless pipe with an outer diameter of 15.8 mm and an external detector with a dimension of 100×100 mm2 placed at the opposite side of the internal detector. Integrated images of 511-keV gamma rays, NIR fluorescence, and visible light were obtained simultaneously. The 511-keV gamma image could be clearly seen with the acquisition of 5 s, while NIR and visible images could be presented in real time. This multimodal system has the potential for improving the surgery time and the quality of patient care.

Published

2019

7. Intraoperative near-infrared fluorescence imaging and spectroscopy identifies residual tumor cells in wounds

Author

Shuming Nie, Arjun G. Yodh, Giorgos C. Karakousis, Ollin Venegas, Amy C. Durham, Olugbenga T. Okusanya, Jane Keating, Charuhas Deshpande, David E. Holt, Sunil Singhal, Brian Madajewski, and Ashwin B. Parthasarathy

Subjects

Adult, Indocyanine Green, Male, medicine.medical_specialty, Near-Infrared Fluorescence Imaging, Pathology, Neoplasm, Residual, Research Papers: Imaging, Biomedical Engineering, Tumor cells, Pilot Projects, Fluorescence spectroscopy, Biomaterials, chemistry.chemical_compound, Dogs, medicine, Image Processing, Computer-Assisted, Neoplasm, Animals, Humans, Spectroscopy, Near-Infrared, business.industry, Optical Imaging, Cancer, Surgical wound, Sarcoma, Middle Aged, medicine.disease, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, chemistry, Histopathology, business, Nuclear medicine, Indocyanine green

Abstract

Surgery is the most effective method to cure patients with solid tumors, and 50% of all cancer patients undergo resection. Local recurrences are due to tumor cells remaining in the wound, thus we explore near-infrared (NIR) fluorescence spectroscopy and imaging to identify residual cancer cells after surgery. Fifteen canines and two human patients with spontaneously occurring sarcomas underwent intraoperative imaging. During the operation, the wounds were interrogated with NIR fluorescence imaging and spectroscopy. NIR monitoring identified the presence or absence of residual tumor cells after surgery in 14/15 canines with a mean fluorescence signal-to-background ratio (SBR) of ∼16. Ten animals showed no residual tumor cells in the wound bed (mean SBR1-year follow-up. In five animals, the mean SBR of the wound was >15, and histopathology confirmed tumor cells in the postsurgical wound in four/five canines. In the human pilot study, neither patient had residual tumor cells in the wound bed, and both remain disease free at >1.5-year follow up. Intraoperative NIR fluorescence imaging and spectroscopy identifies residual tumor cells in surgical wounds. These observations suggest that NIR imaging techniques may improve tumor resection during cancer operations.

Published

2015

8. Formulation of long-wavelength indocyanine green nanocarriers

Author

William J. Faenza, Robert K. Prud'homme, Douglas H. Adamson, Vikram J. Pansare, and Hoang Jack Lu

Subjects

Indocyanine Green, Materials science, Fluorophore, Research Papers: Imaging, Biomedical Engineering, Analytical chemistry, Nanoparticle, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Ion, Biomaterials, Absorbance, chemistry.chemical_compound, Nanocapsules, Particle Size, Fluorescent Dyes, 021001 nanoscience & nanotechnology, Fluorescence, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, chemistry, Nanocarriers, 0210 nano-technology, Luminescence, Hydrophobic and Hydrophilic Interactions, Indocyanine green

Abstract

Indocyanine green (ICG), a Food and Drug Administration (FDA)-approved fluorophore with excitation and emission wavelengths inside the "optical imaging window," has been incorporated into nanocarriers (NCs) to achieve enhanced circulation time, targeting, and real-time tracking in vivo. While previous studies transferred ICG exogenously into NCs, here, a one-step rapid precipitation process [flash nanoprecipitation (FNP)] creates ICG-loaded NCs with tunable, narrow size distributions from 30 to 180 nm. A hydrophobic ion pair of ICG-tetraoctylammonium or tetradodecylammonium chloride is formed either in situ during FNP or preformed then introduced into the FNP feed stream. The NCs are formulated with cores comprising either vitamin E (VE) or polystyrene (PS). ICG core loadings of 30 wt. % for VE and 10 wt. % for PS are achieved. However, due to a combination of molecular aggregation and Förster quenching, maximum fluorescence (FL) occurs at 10 wt. % core loading. The FL-per-particle scales with core diameter to the third power, showing that FNP enables uniform volume encapsulation. By varying the ICG counter-ion ratio, encapsulation efficiencies above 80% are achieved even in the absence of ion pairing, which rises to 100% with 1∶1 ion pairing. Finally, while ICG ion pairs are shown to be stable in buffer, they partition out of NC cores in under 30 min in the presence of physiological albumin concentrations.

Published

2017

9. Review of fluorescence guided surgery systems: identification of key performance capabilities beyond indocyanine green imaging

Author

Alisha V. DSouza, Kimberley S. Samkoe, Brian W. Pogue, Eric Henderson, and Huiyun Lin

Subjects

Indocyanine Green, medicine.medical_specialty, Fluorescence-lifetime imaging microscopy, Biomedical Engineering, 01 natural sciences, 010309 optics, Biomaterials, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, 0103 physical sciences, medicine, Humans, Sensitivity (control systems), Lighting, Review Papers, Fluorescent Dyes, business.industry, Optical Imaging, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Surgery, Identification (information), Image-guided surgery, Surgery, Computer-Assisted, chemistry, Feature (computer vision), 030220 oncology & carcinogenesis, Key (cryptography), business, Indocyanine green, Clearance

Abstract

There is growing interest in using fluorescence imaging instruments to guide surgery, and the leading options for open-field imaging are reviewed here. While the clinical fluorescence-guided surgery (FGS) field has been focused predominantly on indocyanine green (ICG) imaging, there is accelerated development of more specific molecular tracers. These agents should help advance new indications for which FGS presents a paradigm shift in how molecular information is provided for resection decisions. There has been a steady growth in commercially marketed FGS systems, each with their own differentiated performance characteristics and specifications. A set of desirable criteria is presented to guide the evaluation of instruments, including: (i) real-time overlay of white-light and fluorescence images, (ii) operation within ambient room lighting, (iii) nanomolar-level sensitivity, (iv) quantitative capabilities, (v) simultaneous multiple fluorophore imaging, and (vi) ergonomic utility for open surgery. In this review, United States Food and Drug Administration 510(k) cleared commercial systems and some leading premarket FGS research systems were evaluated to illustrate the continual increase in this performance feature base. Generally, the systems designed for ICG-only imaging have sufficient sensitivity to ICG, but a fraction of the other desired features listed above, with both lower sensitivity and dynamic range. In comparison, the emerging research systems targeted for use with molecular agents have unique capabilities that will be essential for successful clinical imaging studies with low-concentration agents or where superior rejection of ambient light is needed. There is no perfect imaging system, but the feature differences among them are important differentiators in their utility, as outlined in the data and tables here.

Published

2016

10. Dynamic multispectral NIR/SWIR for in vivo lymphovascular architectural and functional quantification.

Author

Hansen, Christopher, Jagtap, Jaidip, Parchur, Abdul, Sharma, Gayatri, Shafiee, Shayan, Sinha, Sayantan, Himburg, Heather, and Joshi, Amit

Subjects

SILVER sulfide, INDOCYANINE green, QUANTUM dots, INTRADERMAL injections, CONTRAST media

Abstract

Significance: Although the lymphatic system is the second largest circulatory system in the body, there are limited techniques available for characterizing lymphatic vessel function. We report shortwave-infrared (SWIR) imaging for minimally invasive in vivo quantification of lymphatic circulation with superior contrast and resolution compared with near-infrared first window imaging. Aim: We aim to study the lymphatic structure and function in vivo via SWIR fluorescence imaging. Approach: We evaluated subsurface lymphatic circulation in healthy, adult immunocompromised salt-sensitive Sprague--Dawley rats using two fluorescence imaging modalities: near-infrared first window (NIR-I, 700 to 900 nm) and SWIR (900 to 1800 nm) imaging. We also compared two fluorescent imaging probes: indocyanine green (ICG) and silver sulfide quantum dots (QDs) as SWIR lymphatic contrast agents following intradermal footpad delivery in these rats. Results: SWIR imaging exhibits reduced scattering and autofluorescence background relative to NIR-I imaging. SWIR imaging with ICG provides 1.7 times better resolution and sensitivity than NIR-I, and SWIR imaging with QDs provides nearly two times better resolution and sensitivity with enhanced vessel distinguishability. SWIR images thus provide a more accurate estimation of in vivo vessel size than conventional NIR-I images. Conclusions: SWIR imaging of silver sulfide QDs into the intradermal footpad injection provides superior image resolution compared with conventional imaging techniques using NIR-I imaging with ICG dye. [ABSTRACT FROM AUTHOR]

Published

2024

11. Real-time identification of life-threatening necrotizing soft-tissue infections using indocyanine green fluorescence imaging.

Author

Ray, Gabrielle S., Streeter, Samuel S., Bateman, Logan M., Elliott, Jonathan Thomas, and Henderson, Eric R.

Subjects

INDOCYANINE green, FLUORESCENCE, TERTIARY care, INTRAVENOUS therapy

Abstract

Significance: Necrotizing soft-tissue infections (NSTIs) are life-threatening infections with a cumulative case fatality rate of 21%. The initial presentation of an NSTI is non-specific, frequently leading to misdiagnosis and delays in care. No current strategies yield an accurate, real-time diagnosis of an NSTI. Aim: A first-in-kind, observational, clinical pilot study tested the hypothesis that measurable fluorescence signal voids occur in NSTI-affected tissues following intravenous administration and imaging of perfusion-based indocyanine green (ICG) fluorescence. This hypothesis is based on the established knowledge that NSTI is associated with local microvascular thrombosis. Approach: Adult patients presenting to the Emergency Department of a tertiary care medical center at high risk for NSTI were prospectively enrolled and imaged with a commercial fluorescence imager. Single-frame fluorescence snapshot and first-pass perfusion kinetic parameters--ingress slope (IS), time-to-peak (TTP) intensity, and maximum fluorescence intensity (IMAX)--were quantified using a dynamic contrast-enhanced fluorescence imaging technique. Clinical variables (comorbidities, blood laboratory values), fluorescence parameters, and fluorescence signal-to-background ratios (SBRs) were compared to final infection diagnosis. Results: Fourteen patients were enrolled and imaged (six NSTI, six cellulitis, one diabetes mellitus-associated gangrene, and one osteomyelitis). Clinical variables demonstrated no statistically significant differences between NSTI and non-NSTI patient groups (p-value ≥ 0.22). All NSTI cases exhibited prominent fluorescence signal voids in affected tissues, including tissue features not visible to the naked eye. All cellulitis cases exhibited a hyperemic response with increased fluorescence and no distinct signal voids. Median lesion-to-background tissue SBRs based on snapshot, IS, TTP, and IMAX parameter maps ranged from 3.2 to 9.1, 2.2 to 33.8, 1.0 to 7.5, and 1.5 to 12.7, respectively, for the NSTI patient group. All fluorescence parameters except TTP demonstrated statistically significant differences between NSTI and cellulitis patient groups (p-value < 0.05). Conclusions: Real-time, accurate discrimination of NSTIs compared with nonnecrotizing infections may be possible with perfusion-based ICG fluorescence imaging. [ABSTRACT FROM AUTHOR]

Published

2024

12. Near-infrared imaging of head and neck squamous cell carcinoma using indocyanine green that targets the αvβ6 peptide.

Author

Yuan Yuan, Tengfei Fan, Jingbo Wang, Ying Yuan, and Xiaofeng Tao

Subjects

NECK, SQUAMOUS cell carcinoma, INDOCYANINE green, PEPTIDES, EPIDERMAL growth factor receptors, POLYMERASE chain reaction

Abstract

Significance: Head and neck squamous cell carcinoma (HNSCC) has a particularly poor prognosis. Improving the surgical resection boundary, reducing local recurrence, and ultimately ameliorating the overall survival rate are the treatment goals. Aim: To obtain a complete surgical resection (R0 resection), we investigated the use of a fluorescent imaging probe that targets the integrin subtype αvβ6, which is upregulated in many kinds of epithelial cancer, using animal models. Approach: αvβ6 expression was detected using polymerase chain reaction (PCR) and immunoprotein blotting of human tissues for malignancy. Protein expression localization was observed. αvβ6 and epidermal growth factor receptor (EGFR) were quantified by PCR and immunoprotein blotting, and the biosafety of targeting the αvβ6 probe material was examined using Cell Counting Kit-8 assays. Indocyanine green (ICG) was used as a control to determine the localization of the probe at the cellular level. In vivo animal experiments were conducted through tail vein injections to evaluate the probe’s imaging effect and to confirm its targeting in tissue sections. Results: αvβ6 expression was higher than EGFR expression in HNSCC, and the probe showed good targeting in in vivo and in vitro experiments with a good safety profile. Conclusions: The ICG-αvβ6 peptide probe is an exceptional and sensitive imaging tool for HNSCC that can distinguish among tumor, normal, and inflammatory tissues. [ABSTRACT FROM AUTHOR]

Published

2024

13. Semi-automatic standardized analysis method to objectively evaluate near-infrared fluorescent dyes in image-guided surgery.

Author

Dijkhuis, Tom H., Bijlstra, Okker D., Warmerdam, Mats I., Faber, Robin A., Linders, Daan G. J., Galema, Hidde A., Broersen, Alexander, Dijkstra, Jouke, Kuppen, Peter J. K., Vahrmeijer, Alexander L., and Mieoga, Jan Sven David

Subjects

FLUORESCENT dyes, COMPUTER-assisted surgery, INTRACLASS correlation, INDOCYANINE green, IMAGE analysis, FLUORIMETRY

Abstract

Significance: Near-infrared fluorescence imaging still lacks a standardized, objective method to evaluate fluorescent dye efficacy in oncological surgical applications. This results in difficulties in translation between preclinical to clinical studies with fluorescent dyes and in the reproduction of results between studies, which in turn hampers further clinical translation of novel fluorescent dyes. Aim: Our aim is to develop and evaluate a semi-automatic standardized method to objectively assess fluorescent signals in resected tissue. Approach: A standardized imaging procedure was designed and quantitative analysis methods were developed to evaluate non-targeted and tumor-targeted fluorescent dyes. The developed analysis methods included manual selection of region of interest (ROI) on white light images, automated fluorescence signal ROI selection, and automatic quantitative image analysis. The proposed analysis method was then compared with a conventional analysis method, where fluorescence signal ROIs were manually selected on fluorescence images. Dice similarity coefficients and intraclass correlation coefficients were calculated to determine the inter- and intraobserver variabilities of the ROI selections and the determined signal- and tumor-tobackground ratios. Results: The proposed non-targeted fluorescent dyes analysis method showed statistically significantly improved variabilities after application on indocyanine green specimens. For specimens with the targeted dye SGM-101, the variability of the background ROI selection was statistically significantly improved by implementing the proposed method. Conclusion: Semi-automatic methods for standardized quantitative analysis of fluorescence images were successfully developed and showed promising results to further improve the reproducibility and standardization of clinical studies evaluating fluorescent dyes. [ABSTRACT FROM AUTHOR]

Published

2024

14. Automatic correction of motion artifact in dynamic contrast-enhanced fluorescence imaging during open orthopedic surgery.

Author

Yue Tang, Gitajn, Ida Leah, Xu Cao, Xinyue Han, Elliott, Jonathan T., Bateman, Logan M., Malskis, Bethany S., Fisher, Lillian A., Sin, Jessica M., Henderson, Eric R., and Shudong Jiang

Subjects

CONTRAST-enhanced magnetic resonance imaging, ORTHOPEDIC surgery, FLUORESCENCE, PERFUSION, RESPIRATION, INDOCYANINE green

Abstract

Significance: Indocyanine green-based dynamic contrast-enhanced fluorescence imaging (DCE-FI) can objectively assess bone perfusion intraoperatively. However, it is susceptible to motion artifact due to patients' involuntary respiration and mechanical disturbance. Reducing motion artifacts would significantly improve DCE-FI for orthopedic surgical guidance. Aim: Our primary objective is to develop an automated correction method to reduce motion artifacts in DCE-FI and improve the accuracy of bone perfusion assessment. Approach: We developed an automated motion correction approach based on frame-by-frame mutual information (MI) and validated the effectiveness of this approach in various phantom studies and patient images from 45 imaging sessions of fifteen amputees. Results: The MI-based correction reduced motion artifacts by 93% for mechanical disturbances and 76% for simulated respiration in phantom studies. Patient images show improved alignment, improved kinetic curves, and restored bone perfusionrelated parameters with an average correction of 4.3 and 9.6 mm in x- and y-axes per session. Conclusions: The automated MI-based motion correction was able to eliminate motion artifacts effectively and significantly improved the quantitative assessment of bone perfusion by DCE-FI. [ABSTRACT FROM AUTHOR]

Published

2024

15. Functionalized erythrocyte-derived optical nanoparticles to target ephrin-B2 ligands.

Author

Hanley, Taylor, Rong Yin, Mac, Jenny T., Wenbin Tan, and Anvari, Bahman

Subjects

ERYTHROPOIETIN receptors, EPHRIN receptors, LIGANDS (Biochemistry), INDOCYANINE green, ENDOTHELIAL cells, CELL imaging

Abstract

Over- or under-expression of erythropoietin-production human hepatocellular receptors (Eph) and their ligands are associated with various diseases. Therefore, these molecular biomarkers can potentially be used as binding targets for the delivery of therapeutic and/or imaging agents to cells characterized by such irregular expressions. We have engineered nanoparticles derived from erythrocytes and doped with the near-infrared (NIR) FDA-approved dye, indocyanine green. We refer to these nanoparticles as NIR erythrocyte-derived transducers (NETs). We functionalized the NETs with the ligand-binding domain of a particular Eph receptor, EphB1, to target the genetically modified human dermal microvascular endothelial cells (hDMVECs) with coexpression of EphB1 receptor and its ligand ephrin-B2. This cell model mimics the pathological phenotypes of lesional endothelial cells (ECs) in port wine stains (PWSs). Our quantitative fluorescence imaging results demonstrate that such functionalized NETs bind to the ephrin-B2 ligands on these hDMVECs in a dose-dependent manner that varies sigmoidally with the number density of the particles. These nanoparticles may potentially serve as agents to target PWS lesional ECs and other diseases characterized with over-expression of Eph receptors or their associated ligands to mediate phototherapy. [ABSTRACT FROM AUTHOR]

Published

2019

16. Photothermal treatment of port-wine stains using erythrocyte-derived particles doped with indocyanine green: a theoretical study.

Author

Burns, Joshua M., Wangcun Jia, Nelson, J. Stuart, Majaron, Boris, and Anvari, Bahman

Subjects

INDOCYANINE green, THERAPEUTICS, DYE lasers, BLOOD vessels, PULSED lasers

Abstract

Pulsed dye laser irradiation in the wavelength range of 585 to 600 nm is currently the gold standard for treatment of port-wine stains (PWSs). However, this treatment method is often ineffective for deeply seated blood vessels and in individuals with moderate to heavy pigmentation. Use of optical particles doped with the FDA-approved near-infrared (NIR) absorber, indocyanine green (ICG), can potentially provide an effective method to overcome these limitations. Herein, we theoretically investigate the effectiveness of particles derived from erythrocytes, which contain ICG, in mediating photothermal destruction of PWS blood vessels. We refer to these particles as NIR erythrocyte-derived transducers (NETs). Our theoretical model consists of a Monte Carlo algorithm to estimate the volumetric energy deposition, a finite elements approach to solve the heat diffusion equation, and a damage integral based on an Arrhenius relationship to quantify tissue damage. The model geometries include simulated PWS blood vessels as well as actual human PWS blood vessels plexus obtained by the optical coherence tomography. Our simulation results indicate that blood vessels containing micron- or nano-sized NETs and irradiated at 755 nm have higher levels of photothermal damage as compared to blood vessels without NETs irradiated at 585 nm. Blood vessels containing micron-sized NETs also showed higher photothermal damage than blood vessels containing nano-sized NETs. The theoretical model presented can be used in guiding the fabrication of NETs with patient-specific optical properties to allow for personalized treatment based on the depth and size of blood vessels as well as the pigmentation of the individual's skin. [ABSTRACT FROM AUTHOR]

Published

2018

17. Intraoperative brain tumor resection with indocyanine green using augmented microscopy.

Author

Watson, Jeffrey R., Martirosyan, Nikolay, Lemole, G. Michael, Lemole, Michael, and Romanowskia, Marek

Subjects

BRAIN surgery, BRAIN tumor treatment, INDOCYANINE green, FLUORESCENCE, MEDICAL microscopy, DIAGNOSTIC imaging

Abstract

Treatment outcomes for brain cancer have seen dismal improvements over the last two decades as evident in available statistical data. Efforts to address this challenge include development of near-infrared contrast agents for improvements in diagnostic and therapeutic modalities. This creates a need for imaging technologies that can support the intraoperative use of such agents. Here, we report implementation of a recently introduced augmented microscope in combination with indocyanine green (ICG), a near-infrared contrast agent, for surgical image guidance of a glioma resection in a rat model. Luc-C6 cells were implanted in rats in the left-frontal lobe and grown for 22 days. Surgical resection was performed by a neurosurgeon using the augmented microscope with ICG contrast. ICG accumulated in the tumor tissue due to enhanced permeation and retention from the compromised blood-brain barrier. Videos and images were acquired to evaluate image quality and resection margins. The augmented microscope highlighted tumor tissue regions via visualization of ICG fluorescence and was capable of guiding the rat glioma resection. [ABSTRACT FROM AUTHOR]

Published

2018

18. Low-cost high sensitivity pulsed endomicroscopy to visualize tricolor optical signatures.

Author

Krstajić, Nikola, Mills, Bethany, Murray, Ian, Marshall, Adam, Norberg, Dominic, Craven, Thomas H., Emanuel, Philip, Choudhary, Tushar R., Williams, Gareth O. S., Scholefield, Emma, Akram, Ahsan R., Davie, Andrew, Hirani, Nik, Bruce, Annya, Moore, Anne, Bradley, Mark, and Dhaliwal, Kevin

Subjects

LIGHT emitting diodes, OPTICAL properties, INDOCYANINE green, BIOFLUORESCENCE, COST effectiveness, VISUALIZATION

Abstract

A highly sensitive, modular three-color fluorescence endomicroscopy imaging platform spanning the visible to near-infrared (NIR) range is demonstrated. Light-emitting diodes (LEDs) were sequentially pulsed along with the camera acquisition to provide up to 20 frames per second (fps) three-color imaging performance or 60 fps single color imaging. The system was characterized for bacterial and cellular molecular imaging in ex vivo human lung tissue and for bacterial and indocyanine green imaging in ex vivo perfused sheep lungs. A practical method to reduce background tissue autofluorescence is also proposed. The platform was clinically translated into six patients with pulmonary disease to delineate healthy, cancerous, and fibrotic tissue autofluorescent structures. The instrument is the most broadband clinical endomicroscopy system developed to date (covering visible to the NIR, 500 to 900 nm) and demonstrates significant potential for future clinical utility due to its low cost and modular capability to suit a wide variety of molecular imaging applications. [ABSTRACT FROM AUTHOR]

Published

2018

19. Benchtop and animal validation of a portable fluorescence microscopic imaging system for potential use in cholecystectomy.

Author

Jian Ye, Guanghui Liu, Peng Liu, Shiwu Zhang, Pengfei Shao, Smith, Zachary J., Chenhai Liu, and Xu, Ronald X.

Subjects

FLUORESCENCE microscopy, CHOLECYSTECTOMY, INDOCYANINE green, MAGNETIC resonance imaging, BILE ducts, WOUNDS & injuries

Abstract

We propose a portable fluorescence microscopic imaging system (PFMS) for intraoperative display of biliary structure and prevention of iatrogenic injuries during cholecystectomy. The system consists of a light source module, a camera module, and a Raspberry Pi computer with an LCD. Indocyanine green (ICG) is used as a fluorescent contrast agent for experimental validation of the system. Fluorescence intensities of the ICG aqueous solution at different concentration levels are acquired by our PFMS and compared with those of a commercial Xenogen IVIS system. We study the fluorescence detection depth by superposing different thicknesses of chicken breast on an ICG-loaded agar phantom. We verify the technical feasibility for identifying potential iatrogenic injury in cholecystectomy using a rat model in vivo. The proposed PFMS system is portable, inexpensive, and suitable for deployment in resource-limited settings. [ABSTRACT FROM AUTHOR]

Published

2018

20. Assessment of open-field fluorescence guided surgery systems: implementing a standardized method for characterization and comparison.

Author

Ochoa, Marien I., Ruiz, Alberto, LaRochelle, Ethan, Reed, Matthew, Berber, Eren, Poultsides, George, and Pogue, Brian W.

Subjects

FLUORESCENCE, PATIENT decision making, IMAGING systems, INDOCYANINE green, LAPAROSCOPIC surgery

Abstract

Fluorescence guided surgery (FGS) has demonstrated improvements in decision making and patient outcomes for a wide range of surgical procedures. Not only can FGS systems provide a higher level of structural perfusion accuracy in tissue reconstruction cases but they can also serve for real-time functional characterization. Multiple FGS devices have been Food and Drug administration (FDA) cleared for use in open and laparoscopic surgery. Despite the rapid growth of the field, there has been a lack standardization methods. This work overviews commonalities inherent to optical imaging methods that can be exploited to produce such a standardization procedure. Furthermore, a system evaluation pipeline is proposed and executed through the use of photo-stable indocyanine green fluorescence phantoms. Five different FDA-approved open-field FGS systems are used and evaluated with the proposed method. The proposed pipeline encompasses the following characterization: (1) imaging spatial resolution and sharpness, (2) sensitivity and linearity, (3) imaging depth into tissue, (4) imaging system DOF, (5) uniformity of illumination, (6) spatial distortion, (7) signal to background ratio, (8) excitation bands, and (9) illumination wavelength and power. The results highlight how such a standardization approach can be successfully implemented for inter-system comparisons as well as how to better understand essential features within each FGS setup. Despite clinical use being the end goal, a robust yet simple standardization pipeline before clinical trials, such as the one presented herein, should benefit regulatory agencies, manufacturers, and end-users to better assess basic performance and improvements to be made in next generation FGS systems. [ABSTRACT FROM AUTHOR]

Published

2023

21. Minimizing near-infrared autofluorescence in preclinical imaging with diet and wavelength selection.

Author

Sun, Yidan, Zhong, Xingjian, and Dennis, Allison M.

Subjects

BIOFLUORESCENCE, WAVELENGTHS, DIET, CONTRAST media, INDOCYANINE green, FLUORESCENCE

Abstract

Preclinical fluorescence imaging with NIR-I (700 to 900 nm) illumination and short-wave infrared or NIR-II (1000 to 1700 nm) emission increases tissue penetration depth and improves resolution through decreased scattering. Background autofluorescence decreases signal-to-background ratios (SBR) in fluorescence imaging; maximizing SBR will further improve the impact of deep tissue imaging. The impact of rodent diet, illumination wavelength, and emission range on the background fluorescence and contrast agent SBR were determined to assist with the experimental design of future imaging studies. Following illumination with 670, 760, or 808 nm, autofluorescence in the NIR-I (<975 nm), NIR-II (>1000 nm), and NIR-II LP (>1250 nm) regions was assessed in mice fed chow or a purified diet using an IR VIVO preclinical imager (Photon, Etc.). Comparison of the SBR of liver-localized indocyanine green in the various imaging conditions indicated when gut autofluorescence was a problematic confounder. Mice fed chow exhibit high levels of background autofluorescence in the gastrointestinal tract and, to a lesser extent, skin when illuminated with 670 nm light for NIR-I imaging (700 to 975 nm), interfering with the identification of fluorescently labeled tissue. Background autofluorescence was reduced by more than two orders of magnitude by any of the following changes: (1) purified diet; (2) excitation with 760 or 808 nm illumination; or (3) emission in the NIR-II (1000 to 1600 or 1250 to 1600 nm). Although the SBR was generally sufficient for feature identification except when imaging of chow-fed mice with 670 nm excitation and NIR-I emission, switching to a purified diet, using longer excitation wavelengths, or using longer emission wavelengths improved SBR significantly. Systematic comparison of imaging conditions and diet highlights the reduction in autofluorescence and increase in SBR enabled by intentional choices in the experimental parameters including diet, excitation wavelength, and emission wavelength range. [ABSTRACT FROM AUTHOR]

Published

2023

22. Formulation of long-wavelength indocyanine green nanocarriers.

Author

Pansare, Vikram J., Faenza, William J., Hoang Lu, Adamson, Douglas H., and Prud'homme, Robert K.

Subjects

INDOCYANINE green, DRUG approval, NANOCARRIERS, ION pairs, WAVELENGTHS

Abstract

Indocyanine green (ICG), a Food and Drug Administration (FDA)-approved fluorophore with excitation and emission wavelengths inside the "optical imaging window," has been incorporated into nanocarriers (NCs) to achieve enhanced circulation time, targeting, and real-time tracking in vivo. While previous studies transferred ICG exogenously into NCs, here, a one-step rapid precipitation process [flash nanoprecipitation (FNP)] creates ICG-loaded NCs with tunable, narrow size distributions from 30 to 180 nm. A hydrophobic ion pair of ICGtetraoctylammonium or tetradodecylammonium chloride is formed either in situ during FNP or preformed then introduced into the FNP feed stream. The NCs are formulated with cores comprising either vitamin E (VE) or polystyrene (PS). ICG core loadings of 30 wt. % for VE and 10 wt. % for PS are achieved. However, due to a combination of molecular aggregation and Förster quenching, maximum fluorescence (FL) occurs at 10 wt. % core loading. The FL-per-particle scales with core diameter to the third power, showing that FNP enables uniform volume encapsulation. By varying the ICG counter-ion ratio, encapsulation efficiencies above 80% are achieved even in the absence of ion pairing, which rises to 100% with 1:1 ion pairing. Finally, while ICG ion pairs are shown to be stable in buffer, they partition out of NC cores in under 30 min in the presence of physiological albumin concentrations. [ABSTRACT FROM AUTHOR]

Published

2017

23. Cranial nerve contrast using nerve-specific fluorophores improved by paired-agent imaging with indocyanine green as a control agent.

Author

Torres, Veronica C., Vuong, Victoria D., Wilson, Todd, Wewel, Joshua, Byrne, Richard W., and Tichauer, Kenneth M.

Subjects

CRANIAL nerves, FLUORESCENCE, INDOCYANINE green, CONTRAST media, SURGERY safety measures

Abstract

Nerve preservation during surgery is critical because damage can result in significant morbidity. This remains a challenge especially for skull base surgeries where cranial nerves (CNs) are involved because visualization and access are particularly poor in that location. We present a paired-agent imaging method to enhance identification of CNs using nerve-specific fluorophores. Two myelin-targeting imaging agents were evaluated, Oxazine 4 and Rhodamine 800, and coadministered with a control agent, indocyanine green, either intravenously or topically in rats. Fluorescence imaging was performed on excised brains ex vivo, and nerve contrast was evaluated via paired-agent ratiometric data analysis. Although contrast was improved among all experimental groups using paired-agent imaging compared to conventional, solely targeted imaging, Oxazine 4 applied directly exhibited the greatest enhancement, with a minimum 3 times improvement in CNs delineation. This work highlights the importance of accounting for nonspecific signal of targeted agents, and demonstrates that paired-agent imaging is one method capable of doing so. Although staining, rinsing, and imaging protocols need to be optimized, these findings serve as a demonstration for the potential use of paired-agent imaging to improve contrast of CNs, and consequently, surgical outcome. [ABSTRACT FROM AUTHOR]

Published

2017

24. Morphology alterations of skin and subcutaneous fat at NIR laser irradiation combined with delivery of encapsulated indocyanine green.

Author

Yanina, Irina Yu., Navolokin, Nikita A., Svenskaya, Yulia I., Bucharskaya, Alla B., Maslyakova, Galina N., Gorin, Dmitry A., Sukhorukov, Gleb B., and Tuchin, Valery V.

Subjects

OBESITY in animals, RATS, PHOTOCHEMISTRY, INDOCYANINE green, NEAR infrared spectroscopy

Abstract

The goal of this study is to quantify the impact of the in vivo photochemical treatment of rats with obesity using indocyanine green (ICG) dissolved in saline or dispersed in an encapsulated form at NIR laser irradiation, which was monitored by tissue sampling and histochemistry. The subcutaneous injection of the ICG solution or ICG encapsulated into polyelectrolyte microcapsules, followed by diode laser irradiation (808 nm, 8 W/cm², 1 min), resulted in substantial differences in lipolysis of subcutaneous fat. Most of the morphology alterations occurred in response to the laser irradiation if a free-ICG solution had been injected. In such conditions, membrane disruption, stretching, and even delamination in some cases were observed for a number of cells. The encapsulated ICG aroused similar morphology changes but with weakly expressed adipocyte destruction under the laser irradiation. The Cochran Q test rendered the difference between the treatment alternatives statistically significant. By this means, laser treatment using the encapsulated form of ICG seems more promising and could be used for safe layerwise laser treatment of obesity and cellulite. [ABSTRACT FROM AUTHOR]

Published

2017

25. Near-infrared angiography for critical limb ischemia in a diabetic murine model.

Author

Garcia, Missael, Zayed, Mohamed A., Park, Kyoung-mi, and Gruev, Viktor

Subjects

ARTERIAL diseases, ISCHEMIA diagnosis, DIAGNOSIS of diabetes, RADIOSCOPIC diagnosis, BLOOD circulation disorders, DIAGNOSIS

Abstract

Peripheral arterial disease (PAD) is a highly prevalent disease process that afflicts more than 20% of individuals with diabetes. Progression of PAD in the setting of diabetes can lead to critical limb ischemia (CLI), which is associated with increased risk of wounds, gangrene, and limb loss. Prompt noninvasive evaluation of limbs affected by PAD progression and CLI is currently limited. Here, we evaluate the utility of a customdesigned multispectral imaging system for fluorescence-based near-infrared angiography and compare it to the existing gold standard of laser-scanning Doppler perfusion assessments. Due to its higher resolution and fluorescence sensitivity, near-infrared angiography demonstrates a greater capacity to characterize altered dynamic arterial perfusion in a clinically relevant diabetic murine model for CLI. Furthermore, we demonstrate that our imaging system can accurately track arterial perfusion recovery over time following induced ischemia, and reveal unique phenotypic differences in the setting of diabetes. [ABSTRACT FROM AUTHOR]

Published

2017

26. Fluorescence lifetime-based contrast enhancement of indocyanine green-labeled tumors.

Author

Kumar, Anand T. N., Carp, Stefan A., Jing Yang, Ross, Alana, Medarova, Zdravka, and Ran, Chongzhao

Subjects

FLUORESCENCE spectroscopy, INDOCYANINE green, HETEROCYCLIC compounds, TUMOR diagnosis, OPTICAL properties

Abstract

Although the development of tumor-targeted fluorescent probes is a major area of investigation, it will be several years before these probes are realized for clinical use. Here, we report an approach that employs indocyanine-green (ICG), a clinically approved, nontargeted dye, in conjunction with fluorescence lifetime (FLT) detection to provide high accuracy for tumor-tissue identification in mouse models of subcutaneous human breast and brain tmors. The improved performance relies on the distinct FLTs of ICG within tumors versus tissue autofluorescence and is further aided by the well-known enhanced permeability and retention of ICG in tumors and the clearance of ICG from normal tissue several hours after intravenous injection. We demonstrate that FLT detection can provide more than 98% sensitivity and specificity, and a 10-fold reduction in error rates compared to intensity-based detection. Our studies suggest the significant potential of FLTcontrast for accurate tumor-tissue identification using ICG and other targeted probes under development, both for intraoperative imaging and for ex-vivo margin assessment of surgical specimens. [ABSTRACT FROM AUTHOR]

Published

2017

27. Mapping estimates of vascular permeability with a clinical indocyanine green fluorescence imaging system in experimental pancreatic adenocarcinoma tumors.

Author

Reed, Matthew S., Ochoa, Marien, Tichauer, Kenneth M., Weichmann, Ashley, Doyley, Marvin M., and Pogue, Brian W.

Subjects

PANCREATIC tumors, IMAGING systems, INDOCYANINE green, PERMEABILITY, FLUORESCENCE, CYANINES

Abstract

Pancreatic cancer tumors are known to be avascular, but their neovascular capillaries are still chaotic leaky vessels. Capillary permeability could have significant value for therapy assessment, and its quantification might be possible with macroscopic imaging of indocyanine green (ICG) kinetics in tissue. The capacity of using standard fluorescence surgical systems for ICG kinetic imaging as a probe for capillary leakage was evaluated using a clinical surgical fluorescence imaging system, as interpreted through vascular permeability modeling. Xenograft pancreatic adenocarcinoma models were imaged in mice during bolus injection of ICG to capture the kinetics of uptake. Image analysis included ratiometric data, normalization, and match to theoretical modeling. Kinetic data were converted into the extraction fraction of the capillary leakage. Pancreatic tumors were usually less fluorescent than the surrounding healthy tissues, but still the rate of tumor perfusion could be assessed to quantify capillary extraction. Model simulations showed that flow kinetics stabilized after about 1 min beyond the initial bolus injection and that the relative extraction fraction model estimates matched the experimental data of normalized uptake within the tissue. The kinetics in the time period of 1 to 2 min post-injection provided optimal differential data between AsPC1 and BxPC3 tumors, although high individual variation exists between tumors. ICG kinetic imaging during the initial leakage phase was diagnostic for quantitative vascular permeability within pancreatic tumors. Methods for autogain correction and normalized model-based interpretation allowed for quantification of extraction fraction and difference identification between tumor types in early timepoints. [ABSTRACT FROM AUTHOR]

Published

2023

28. Evaluating clinical near-infrared surgical camera systems with a view to optimizing operator and computational signal analysis.

Author

Dalli, Jeffrey, Jindal, Abhinav, Gallagher, Gareth, Epperlein, Jonathan P., Hardy, Niall P., Malallah, Ra'ed, O'Donoghue, Kilian, Cantillon-Murphy, Padraig, Mac Aonghusa, Pól G., and Cahill, Ronan A.

Subjects

INDOCYANINE green, CAMERAS, FLUORESCENCE angiography, INFRARED cameras, COMPUTER software development, INVERSE functions, DISPLAY systems, FUJIFILM digital cameras

Abstract

As clinical evidence on the colorectal application of indocyanine green (ICG) perfusion angiography accrues, there is also interest in computerizing decision support. However, user interpretation and software development may be impacted by system factors affecting the displayed near-infrared (NIR) signal. We aim to assess the impact of camera positioning on the displayed NIR signal across different open and laparoscopic camera systems. The effects of distance, movement, and target location (center versus periphery) on the displayed fluorescence signal of different systems were measured under electromagnetic stereotactic guidance from an ICG-albumin model and in vivo during surgery. Systems displayed distinct fluorescence performances with variance apparent with scope optical lens configuration (0 deg versus 30 deg), movement, target positioning, and distance. Laparoscopic system readings fitted inverse square function distance-intensity curves with one device and demonstrated a direction dependent sigmoid curve. Laparoscopic cameras presented central targets as brighter than peripheral ones, and laparoscopes with angled optical lens configurations had a diminished field of view. One handheld open system also showed a distance-intensity relationship, whereas the other maintained a consistent signal despite distance, but both presented peripheral targets brighter than central ones. Optimal clinical use and signal computational development requires detailed appreciation of system behaviors. [ABSTRACT FROM AUTHOR]

Published

2023

29. Noninvasive in vivo multispectral optoacoustic imaging of apoptosis in triple negative breast cancer using indocyanine green conjugated phosphatidylserine monoclonal antibody.

Author

Kannadorai, Ravi Kumar, Udumala, Sunil Kumar, and Yu Wing Kwong Sidney

Subjects

NONINVASIVE diagnostic tests, PHOTOACOUSTIC spectroscopy, TRIPLE-negative breast cancer, APOPTOSIS, MONOCLONAL antibodies, INDOCYANINE green, PHOSPHATIDYLSERINES

Abstract

Noninvasive and nonradioactive imaging modality to track and image apoptosis during chemotherapy of triple negative breast cancer is much needed for an effective treatment plan. Phosphatidylserine (PS) is a biomarker transiently exposed on the outer surface of the cells during apoptosis. Its externalization occurs within a few hours of an apoptotic stimulus by a chemotherapy drug and leads to presentation of millions of phospholipid molecules per apoptotic cell on the cell surface. This makes PS an abundant and accessible target for apoptosis imaging. In the current work, we show that PS monoclonal antibody tagged with indocyanine green (ICG) can help to track and image apoptosis using multispectral optoacoustic tomography in vivo. When compared to saline control, the doxorubicin treated group showed a significant increase in uptake of ICG-PS monoclonal antibody in triple negative breast tumor xenografted in NCr nude female mice. Day 5 posttreatment had the highest optoacoustic signal in the tumor region, indicating maximum apoptosis and the tumor subsequently shrank. Since multispectral optoacoustic imaging does not involve the use of radioactivity, the longer the circulatory time of the PS antibody can be exploited to monitor apoptosis over a period of time without multiple injections of commonly used imaging probes such as Tc-99m Annexin V or F-18 ML10. The proposed apoptosis imaging technique involving multispectral optoacoustic tomography, monoclonal antibody, and near-infrared absorbing fluorescent marker can be an effective tool for imaging apoptosis and treatment planning. [ABSTRACT FROM AUTHOR]

Published

2016

30. Review of near-infrared methods for wound assessment.

Author

Sowa, Michael G., Wen-Chuan Kuo, Ko, Alex C-T., and Armstrong, David G.

Subjects

NEAR infrared spectroscopy, WOUND care, INDOCYANINE green, CYANINES, FLUORESCENCE

Abstract

Wound management is a challenging and costly problem that is growing in importance as people are living longer. Instrumental methods are increasingly being relied upon to provide objective measures of wound assessment to help guide management. Technologies that employ near-infrared (NIR) light form a prominent contingent among the existing and emerging technologies. We review some of these technologies. Some are already established, such as indocyanine green fluorescence angiography, while we also speculate on others that have the potential to be clinically relevant to wound monitoring and assessment. These various NIR-based technologies address clinical wound management needs along the entire healing trajectory of a wound. [ABSTRACT FROM AUTHOR]

Published

2016

31. Near-infrared indocyanine dye permits real-time characterization of both venous and lymphatic circulation.

Author

Toshikazu Kurahashi, Katsuyuki Iwatsuki, Tetsuro Onishi, Tetsuya Arai, Katsunori Teranishi, and Hitoshi Hirata

Subjects

INDOCYANINE green, FLUOROPHORES, PHARMACOKINETICS, CYCLODEXTRINS in pharmaceutical technology, OPTICAL properties

Abstract

We investigated the optical properties of a near-infrared (NIR) fluorochrome, di-β-cyclodextrin-binding indocyanine derivative (TK-1), and its pharmacokinetic differences with indocyanine green (ICG). TK-1 was designed to have hydrophilic cyclodextrin molecules and, thus, for higher water solubility and smaller particle sizes than the plasma protein-bound ICG. We compared optical properties such as the absorption and fluorescence spectra, quantum yield, and photostability between both dyes in vitro. In addition, we subcutaneously injected a 1 mM solution of TK-1 or ICG into the hind footpad of rats and observed real-time NIR fluorescence intensities in their femoral veins and accompanying lymphatics at the exposed groin site to analyze the dye pharmacokinetics. These optical experiments demonstrated that TK-1 has high water solubility, a low self-aggregation tendency, and high optical and chemical stabilities. Our in vivo imaging showed that TK-1 was transported via peripheral venous flow and lymphatic flow, whereas ICG was drained only through lymphatics. The results of this study showed that lymphatic and venous transport can be differentially regulated and is most likely influenced primarily by particle size, and that TK-1 can enable real-time NIR fluorescence imaging of whole fluids and solute movement via both microvessels and lymphatics, which conventional ICG cannot achieve. [ABSTRACT FROM AUTHOR]

Published

2016

32. Review of fluorescence guided surgery systems: identification of key performance capabilities beyond indocyanine green imaging.

Author

DSouza, Alisha V., Huiyun Lin, Henderson, Eric R., Samkoe, Kimberley S., and Pogue, Brian W.

Subjects

PHOTOLUMINESCENCE, INDOCYANINE green, PROPERTIES of cathode rays, FLUORESCENT lighting, SURGICAL complications

Abstract

There is growing interest in using fluorescence imaging instruments to guide surgery, and the leading options for open-field imaging are reviewed here. While the clinical fluorescence-guided surgery (FGS) field has been focused predominantly on indocyanine green (ICG) imaging, there is accelerated development of more specific molecular tracers. These agents should help advance new indications for which FGS presents a paradigm shift in how molecular information is provided for resection decisions. There has been a steady growth in commercially marketed FGS systems, each with their own differentiated performance characteristics and specifications. A set of desirable criteria is presented to guide the evaluation of instruments, including: (i) real-time overlay of white-light and fluorescence images, (ii) operation within ambient room lighting, (iii) nanomolar-level sensitivity, (iv) quantitative capabilities, (v) simultaneous multiple fluorophore imaging, and (vi) ergonomic utility for open surgery. In this review, United States Food and Drug Administration 510(k) cleared commercial systems and some leading premarket FGS research systems were evaluated to illustrate the continual increase in this performance feature base. Generally, the systems designed for ICG-only imaging have sufficient sensitivity to ICG, but a fraction of the other desired features listed above, with both lower sensitivity and dynamic range. In comparison, the emerging research systems targeted for use with molecular agents have unique capabilities that will be essential for successful clinical imaging studies with low-concentration agents or where superior rejection of ambient light is needed. There is no perfect imaging system, but the feature differences among them are important differentiators in their utility, as outlined in the data and tables here. [ABSTRACT FROM AUTHOR]

Published

2016

33. Indocyanine green as effective antibody conjugate for intracellular molecular targeted photodynamic therapy.

Author

Sijia Wang, Hüttmann, Gereon, Rudnitzki, Florian, Diddens-Tschoeke, Heyke, Zhenxi Zhang, and Rahmanzadeh, Ramtin

Subjects

INDOCYANINE green, PHOTODYNAMIC therapy, IMMUNOGLOBULINS, BACTERIAL conjugation, INTRACELLULAR membranes, ANGIOGRAPHY, CARDIAC output, LIVER function tests, THERAPEUTICS

Abstract

The fluorescent dye indocyanine green (ICG) is clinically approved and has been applied for ophthalmic and intraoperative angiography, measurement of cardiac output and liver function, or as contrast agent in cancer surgery. Though ICG is known for its photochemical effects, it has played a minor role so far in photodynamic therapy or techniques for targeted protein-inactivation. Here, we investigated ICG as an antibody-conjugate for the selective inactivation of the protein Ki-67 in the nucleus of cells. Conjugates of the Ki-67 antibody TuBB-9 with different amounts of ICG were synthesized and delivered into HeLa and OVCAR-5 cells through conjugation to the nuclear localization sequence. Endosomal escape of the macromolecular antibodies into the cytoplasm was optically triggered by photochemical internalization with the photosensitizer BPD. The second light irradiation at 690 nm inactivated Ki-67 and subsequently caused cell death. Here, we show that ICG as an antibody-conjugate can be an effective photosensitizing agent. Best effects were achieved with 1.8 ICG molecules per antibody. Conjugated to antibodies, the ICG absorption peaks vary proportionally with concentration. The absorption of ICG above 650 nm within the optical window of tissue opens the possibility of selective Ki-67 inactivation deep inside of tissues. [ABSTRACT FROM AUTHOR]

Published

2016

34. Fluorescence lifetime measurements in heterogeneous scattering medium.

Author

Goro Nishimura, Awasthi, Kamlesh, and Daisuke Furukawa

Subjects

RADIATIVE transfer equation, LIGHT scattering, FLUORESCENCE spectroscopy, FLUOROPHORES, INDOCYANINE green, TIME-resolved spectroscopy, BIOLOGICAL systems, ALGORITHMS

Abstract

Fluorescence lifetime in heterogeneous multiple light scattering systems is analyzed by an algorithm without solving the diffusion or radiative transfer equations. The algorithm assumes that the optical properties of medium are constant in the excitation and emission wavelength regions. If the assumption is correct and the fluorophore is a single species, the fluorescence lifetime can be determined by a set of measurements of temporal point-spread function of the excitation light and fluorescence at two different concentrations of the fluorophore. This method is not dependent on the heterogeneity of the optical properties of the medium as well as the geometry of the excitation-detection on an arbitrary shape of the sample. The algorithm was validated by an indocyanine green fluorescence in phantom measurements and demonstrated by an in vivo measurement. [ABSTRACT FROM AUTHOR]

Published

2016

35. Principal component analysis of dynamic fluorescence images for diagnosis of diabetic vasculopathy.

Author

Jihye Seo, Yuri An, Jungsul Lee, Taeyun Ku, Yujung Kang, Chulwoo Ahn, and Chulhee Choi

Subjects

INDOCYANINE green, FLUORESCENCE, MULTIPLE correspondence analysis (Statistics), VARIANCES, PEOPLE with diabetes

Abstract

Indocyanine green (ICG) fluorescence imaging has been clinically used for noninvasive visualizations of vascular structures. We have previously developed a diagnostic system based on dynamic ICG fluorescence imaging for sensitive detection of vascular disorders. However, because high-dimensional raw data were used, the analysis of the ICG dynamics proved difficult. We used principal component analysis (PCA) in this study to extract important elements without significant loss of information. We examined ICG spatiotemporal profiles and identified critical features related to vascular disorders. PCA time courses of the first three components showed a distinct pattern in diabetic patients. Among the major components, the second principal component (PC2) represented arterial-like features. The explained variance of PC2 in diabetic patients was significantly lower than in normal controls. To visualize the spatial pattern of PCs, pixels were mapped with red, green, and blue channels. The PC2 score showed an inverse pattern between normal controls and diabetic patients. We propose that PC2 can be used as a representative bioimaging marker for the screening of vascular diseases. It may also be useful in simple extractions of arterial-like features. [ABSTRACT FROM AUTHOR]

Published

2016

36. Optimization of the method for assessment of brain perfusion in humans using contrast-enhanced reflectometry: multidistance time-resolved measurements.

Author

Milej, Daniel, Janusek, Dariusz, Gerega, Anna, Wojtkiewicz, Stanislaw, Sawosz, Piotr, Treszczanowicz, Joanna, Weigl, Wojciech, and Liebert, Adam

Subjects

BRAIN chemistry, PERFUSION, REFLECTOMETRY, TIME-of-flight spectrometry, INDOCYANINE green

Abstract

The aim of the study was to determine optimal measurement conditions for assessment of brain perfusion with the use of optical contrast agent and time-resolved diffuse reflectometry in the near-infrared wavelength range. The source-detector separation at which the distribution of time of flights (DTOF) of photons provided useful information on the inflow of the contrast agent to the intracerebral brain tissue compartments was determined. Series of Monte Carlo simulations was performed in which the inflow and washout of the dye in extra- and intracerebral tissue compartments was modeled and the DTOFs were obtained at different sourcedetector separations. Furthermore, tests on diffuse phantoms were carried out using a time-resolved setup allowing the measurement of DTOFs at 16 source-detector separations. Finally, the setup was applied in experiments carried out on the heads of adult volunteers during intravenous injection of indocyanine green. Analysis of statistical moments of the measured DTOFs showed that the source-detector separation of 6 cm is recommended for monitoring of inflow of optical contrast to the intracerebral brain tissue compartments with the use of continuous wave reflectometry, whereas the separation of 4 cm is enough when the higher-order moments of DTOFs are available. [ABSTRACT FROM AUTHOR]

Published

2015

37. Augmented microscopy: real-time overlay of bright-field and near-infrared fluorescence images.

Author

Watson, Jeffrey R., Gainer, Christian F., Martirosyan, Nikolay, Skoch, Jesse, Michael Lemole, Jr., G., Anton, Rein, and Romanowski, Marek

Subjects

AUGMENTED reality, REAL-time computing, NEAR infrared radiation, OPERATING microscopes, IMAGE analysis software

Abstract

Intraoperative applications of near-infrared (NIR) fluorescent contrast agents can be aided by instrumentation capable of merging the view of surgical field with that of NIR fluorescence. We demonstrate augmented microscopy, an intraoperative imaging technique in which bright-field (real) and electronically processed NIR fluorescence (synthetic) images are merged within the optical path of a stereomicroscope. Under luminance of 100,000 lx, representing typical illumination of the surgical field, the augmented microscope detects 189 nM concentration of indocyanine green and produces a composite of the real and synthetic images within the eyepiece of the microscope at 20 fps. Augmentation described here can be implemented as an add-on module to visualize NIR contrast agents, laser beams, or various types of electronic data within the surgical microscopes commonly used in neurosurgical, cerebrovascular, otolaryngological, and ophthalmic procedures. [ABSTRACT FROM AUTHOR]

Published

2015

38. Development and validation of a custom made indocyanine green fluorescence lymphatic vessel imager.

Author

Pallotta, Olivia J., van Zanten, Malou, McEwen, Mark, Burrow, Lynne, Beesley, Jack, and Piller, Neil

Subjects

INDOCYANINE green, FLUORESCENCE, LYMPHEDEMA, LYMPHATICS, WAVELENGTHS

Abstract

Lymphoedema is a chronic progressive condition often producing significant morbidity. An in-depth understanding of an individual's lymphatic architecture is valuable both in the understanding of underlying pathology and for targeting and tailoring treatment. Severe lower limb injuries resulting in extensive loss of soft tissue require transposition of a flap consisting of muscle and/or soft tissue to close the defect. These patients are at risk of lymphoedema and little is known about lymphatic regeneration within the flap. Indocyanine green (ICG), a water-soluble dye, has proven useful for the imaging of lymphatic vessels. When injected into superficial tissues it binds to plasma proteins in lymph. By exposing the dye to specific wavelengths of light, ICG fluoresces with near-infrared light. Skin is relatively transparent to ICG fluorescence, enabling the visualization and characterization of superficial lymphatic vessels. An ICG fluorescence lymphatic vessel imager was manufactured to excite ICG and visualize real-time fluorescence as it travels through the lymphatic vessels. Animal studies showed successful ICG excitation and detection using this imager. Clinically, the imager has assisted researchers to visualize otherwise hidden superficial lymphatic pathways in patients postflap surgery. Preliminary results suggest superficial lymphatic vessels do not redevelop in muscle flaps. [ABSTRACT FROM AUTHOR]

Published

2015

39. Development of a handheld fluorescence imaging camera for intraoperative sentinel lymph node mapping.

Author

Szyc, Łukasz, Bonifer, Stefanie, Walter, Alfred, Jagemann, Uwe, Grosenick, Dirk, and Macdonald, Rainer

Subjects

NEAR infrared radiation, LIGHT absorption, SENTINEL lymph nodes, INDOCYANINE green, FLUORESCENCE spectroscopy

Abstract

We present a compact fluorescence imaging system developed for real-time sentinel lymph node mapping. The device uses two near-infrared wavelengths to record fluorescence and anatomical images with a single charge-coupled device camera. Experiments on lymph node and tissue phantoms confirmed that the amount of dye in superficial lymph nodes can be better estimated due to the absorption correction procedure integrated in our device. Because of the camera head's small size and low weight, all accessible regions of tissue can be reached without the need for any adjustments. [ABSTRACT FROM AUTHOR]

Published

2015

40. Image overlay solution based on threshold detection for a compact near infrared fluorescence goggle system.

Author

Shengkui Gao, Mondal, Suman B., Nan Zhu, RongGuang Liang, Achilefu, Samuel, and Gruev, Viktor

Subjects

NEAR infrared radiation, FLUORESCENCE microscopy, IMAGING systems, INDOCYANINE green, FLUORESCENCE

Abstract

Near infrared (NIR) fluorescence imaging has shown great potential for various clinical procedures, including intraoperative image guidance. However, existing NIR fluorescence imaging systems either have a large footprint or are handheld, which limits their usage in intraoperative applications. We present a compact NIR fluorescence imaging system (NFIS) with an image overlay solution based on threshold detection, which can be easily integrated with a goggle display system for intraoperative guidance. The proposed NFIS achieves compactness, light weight, hands-free operation, high-precision superimposition, and a real-time frame rate. In addition, the miniature and ultra-lightweight light-emitting diode tracking pod is easy to incorporate with NIR fluorescence imaging. Based on experimental evaluation, the proposed NFIS solution has a lower detection limit of 25 nM of indocyanine green at 27 fps and realizes a highly precise image overlay of NIR and visible images of mice in vivo. The overlay error is limited within a 2-mm scale at a 65-cm working distance, which is highly reliable for clinical study and surgical use. [ABSTRACT FROM AUTHOR]

Published

2015

41. 3D-printed tissue-simulating phantoms for near-infrared fluorescence imaging of rheumatoid diseases.

Author

Schädel-Ebner, Sandra, Hirsch, Ole, Gladytz, Thomas, Gutkelch, Dirk, Licha, Kai, Berger, Jörn, and Grosenick, Dirk

Subjects

FLUORESCENCE, TITANIUM powder, TIME-resolved spectroscopy, FLUORESCENCE spectroscopy, ABSORPTION coefficients, INDOCYANINE green

Abstract

Significance: Fluorescence imaging of rheumatoid diseases with indocyanine green (ICG) is an emerging technique with unique potential for diagnosis and therapy. Device characterization, monitoring of the performance, and further developments of the technique require tissue-equivalent fluorescent phantoms of high stability with appropriate anatomical shapes. Aim: Our investigations aim at the development of a three-dimensional (3D) printing technique to fabricate hand and finger models with appropriate optical properties in the near-infrared spectral range. These phantoms should have fluorescence properties similar to ICG, and excellent photostability and durability over years. Approach: We modified a 3D printing methacrylate photopolymer by adding the fluorescent dye Lumogen IR 765 to the raw material. Reduced scattering and absorption coefficients were adjusted to values representative of the human hand by incorporating titanium dioxide powder and black ink. The properties of printed phantoms of various compositions were characterized using UV/Vis and fluorescence spectroscopy, and time-resolved measurements. Photostability and bleaching were investigated with a hand imager. For comparison, several phantoms with ICG as fluorescent dye were printed and characterized as well. Results: The spectral properties of Lumogen IR 765 are very similar to those of ICG. By optimizing the concentrations of Lumogen, titanium dioxide, and ink, anatomically shaped hand and vessel models with properties equivalent to in vivo investigations with a fluorescence hand imager could be printed. Phantoms with Lumogen IR 765 had an excellent photostability over up to 4 years. In contrast, phantoms printed with ICG showed significant bleaching and degradation of fluorescence over time. Conclusions: 3D printing of phantoms with Lumogen IR 765 is a promising method for fabricating anatomically shaped fluorescent tissue models of excellent stability with spectral properties similar to ICG. The phantoms are well-suited to monitor the performance of hand imagers. Concepts can easily be transferred to other fluorescence imaging applications of ICG. [ABSTRACT FROM AUTHOR]

Published

2022

42. Mouthwash as a non-invasive method of indocyanine green delivery for near-infrared fluorescence dental imaging.

Author

Li, Zhongqiang, Li, Zheng, Zaid, Waleed, Osborn, Michelle L., Li, Yanping, Yao, Shaomian, and Xu, Jian

Subjects

INDOCYANINE green, MOUTHWASHES, SPRAGUE Dawley rats, FLUORESCENCE, ORAL drug administration, SUBCUTANEOUS injections

Abstract

Significance: X-ray imaging serves as the mainstream imaging in dentistry, but it involves risk of ionizing radiation. Aim: This study presents the feasibility of indocyanine green-assisted near-infrared fluorescence (ICG-NIRF) dental imaging with 785-nm NIR laser in the first (ICG-NIRF-I: 700 to 1000 nm) and second (ICG-NIRF-II: 1000 to 1700 nm) NIR wavelengths. Approach: Sprague Dawley rats with different postnatal days were used as animal models. ICG, as a fluorescence agent, was delivered to dental structures by subcutaneous injection (SC) and oral administration (OA). Results: For SC method, erupted and unerupted molars could be observed from ICG-NIRF images at a short imaging time (<1 min). ICG-NIRF-II could achieve a better image contrast in unerupted molars at 24 h after ICG injection. The OA could serve as a non-invasive method for ICG delivery; it could also cause the glow-in-dark effect in unerupted molars. For erupted molars, OA can be considered as mouthwash and exhibits outstanding performance for delivery of ICG dye; erupted molar structures could be observed at a short imaging time (<1 min) and low ICG dose (0.05 mg / kg). Conclusions: Overall, ICG-NIRF with mouthwash could perform in-vivo dental imaging in two NIR wavelengths at a short time and low ICG dose. [ABSTRACT FROM AUTHOR]

Published

2022

43. High-sensitivity dynamic diffuse fluorescence tomography system for fluorescence pharmacokinetics.

Author

Zhang, Limin, Cheng, Nan, Liu, Han, Pan, Yingxue, Zhang, Yanqi, and Gao, Feng

Subjects

FLUORESCENCE, OPTICAL tomography, TOMOGRAPHY, PHARMACOKINETICS, TISSUE metabolism, INDOCYANINE green, DRUG solubility, SQUARE waves

Abstract

Significance: Dynamic diffuse fluorescence tomography (DFT) can recover the static distribution of fluorophores and track dynamic temporal events related to physiological and disease progression. Dynamic imaging indocyanine green (ICG) approved by the food and drug administration is still under-exploited because of its characteristics of low quantum yield and relatively rapid tissue metabolism. Aim: In order to acquire the ICG tomographic image sequences for pharmacokinetic analysis, a dynamic DFT system was proposed. Approach: A fiber-based dynamic DFT system adopts square-wave modulation lock-in photon-counting scheme and series-parallel measurement mode, which possesses high sensitivity, large dynamic range, high anti-ambient light ability in common knowledge, as well as good cost performance. In order to investigate the effectiveness of the proposed system, the measurement stability and the anti-crosstalk—a crucial factor affecting the system parallelization—were assessed firstly, then a series of static phantoms, dynamic phantoms and in vivo mice experiments were conducted to verify the imaging capability. Results: The system has the limited dynamic range of 100 dB, the fluctuation of photon counting within 3%, and channel-to-channel crosstalk ratio better than 1.35. Under the condition of a sufficient signal-to-noise ratio, a complete measurement time for one frame image was 10.08 s. The experimental results of static phantoms with a single target and three targets showed that this system can accurately obtain the positions, sizes, and shapes of the targets and the reconstructed images exhibited a high quantitativeness. Further, the self-designed dynamic phantom experiments demonstrated the capability of the system to capture fast changing fluorescence signals. Finally, the in vivo experiments validated the practical capability of the system to effectively track the ICG metabolism in living mice. Conclusions: These results demonstrate that our proposed system can be utilized for assessing ICG pharmacokinetics, which may provide a valuable tool for tumor detection, drug assessment, and liver function evaluation. [ABSTRACT FROM AUTHOR]

Published

2022

44. Quantitative dynamic near-infrared fluorescence imaging using indocyanine green for analysis of bowel perfusion after mesenteric resection.

Author

Meijer, Ruben P. J., van Manen, Labrinus, Hartgrink, Henk H., Burggraaf, Jacobus, Gioux, Sylvain, Vahrmeijer, Alexander L., and Mieog, J. Sven D.

Subjects

INDOCYANINE green, FLUORESCENCE, INFRARED imaging, PERFUSION, MEDICAL imaging systems, TREATMENT effectiveness

Abstract

Significance: Near-infrared (NIR) fluorescence imaging using indocyanine green (ICG) has proven to be a feasible application for real-time intraoperative assessment of tissue perfusion, although quantification of NIR fluorescence signals is pivotal for standardized assessment of tissue perfusion. Aim: Four patients are described with possible compromised bowel perfusion after mesenteric resection. Based on these patients we want to emphasize the difficulties in the quantification of NIR fluorescence imaging for perfusion analysis. Approach: During image-guided fluorescence assessment, 5 mg of ICG (2.5 mg / ml) was intravenously administered by the anesthesiologist. NIR fluorescence imaging was done with the open camera system of Quest Medical Imaging. Fluorescence data taken from the regions of interest (bowel at risk, transition zone of bowel at risk and adjacent normally perfused bowel, and normally perfused reference bowel) were quantitatively analyzed after surgery for fluorescence intensity-and perfusion time-related parameters. Results: Bowel perfusion, as assessed clinically by independent surgeons based on NIR fluorescence imaging, resulted in different treatment strategies, three with excellent clinical outcome, but one with a perfusion related complication. Post-surgery quantitative analysis of fluorescence dynamics showed different patterns in the affected bowel segment compared to the unaffected reference segments for the four patients. Conclusions: Similar intraoperative fluorescence results could lead to different surgical treatment strategies, which demonstrated the difficulties in interpretation of uncorrected fluorescence signals. Real-time quantification and standardization of NIR fluorescence perfusion imaging could probably aid surgeons in the nearby future. [ABSTRACT FROM AUTHOR]

Published

2021

45. Review of successful pathways for regulatory approvals in open-field fluorescence-guided surgery.

Author

Pogue, Brian W. and Rosenthal, Eben L.

Subjects

FLUORESCENCE angiography, RETINAL imaging, REGULATORY approval, DRUG approval, X-ray imaging, FLUORESCEIN, INDOCYANINE green, CLINICAL indications

Abstract

Significance: The modern use of fluorescence in surgery came iteratively through new devices and pre-existing imaging agents, with indications that were paved via regulatory approvals and device clearances. These events led to a growing set of surgery subspecialty uses. Aim: This article outlines the key milestones that initiated commercially marketed systems and agents by highlighting temporal sequences and strategic decisions between them, with the goal of helping to inform future successes. Approach: A review of successful regulatory approvals and the sequences between them was completed for companies that achieved US Food and Drug Administration (FDA) premarket approval or new drug approvals (NDAs) or device clearances in the fields of fluorescent imaging agents, open surgery imaging devices, and their approved medical indications. Results: Angiography agents, indocyanine green and fluorescein, were approved for human use as absorbing dyes, and this use in retinal imaging was the precursor to lateral translation into tissue perfusion imaging in the last two decades with a growing number of devices. Many FDA cleared devices for open fluorescence-guided surgery used the predicate created by the SPY SP2000 system. This first system was 510(k) cleared for angiography imaging with a unique split predicate from x-ray imaging of vasculature and retinal fluorescence angiography. Since that time, the lateral spread of open surgery devices being cleared for new indications has been occurring with a growth of adoption in surgical subspecialties. Growth into new surgical subspecialties has been achieved by leveraging different NDAs and clearances between indications, such that medical uses have broadened over time. Conclusions: Key decisions made by developers to advance specific device clearances and NDAs have been based upon existing optical fluorescent agents. The historical lessons and regulatory trends in newer indications and contrast agents can help the field evolve via successful investment in new systems and applications. [ABSTRACT FROM AUTHOR]

Published

2021

46. Perspective on optical imaging for functional assessment in musculoskeletal extremity trauma surgery.

Author

Gitajn, Ida L., Slobogean, Gerard P., Henderson, Eric R., von Keudell, Arvind G., Harris, Mitchel B., Scolaro, John A., O'Hara, Nathan N., Elliott, Jonathan T., Pogue, Brian W., and Jiang, Shudong

Subjects

OPTICAL images, TRAUMA surgery, FUNCTIONAL assessment, OPTICAL measurements, OPERATIVE surgery, PERFUSION, BONE regeneration

Abstract

Significance: Extremity injury represents the leading cause of trauma hospitalizations among adults under the age of 65 years, and long-term impairments are often substantial. Restoring function depends, in large part, on bone and soft tissue healing. Thus, decisions around treatment strategy are based on assessment of the healing potential of injured bone and/or soft tissue. However, at the present, this assessment is based on subjective clinical clues and/or cadaveric studies without any objective measure. Optical imaging is an ideal method to solve several of these issues. Aim: The aim is to highlight the current challenges in assessing bone and tissue perfusion/viability and the potentially high impact applications for optical imaging in orthopaedic surgery. Approach: The prospective will review the current challenges faced by the orthopaedic surgeon and briefly discuss optical imaging tools that have been published. With this in mind, it will suggest key research areas that could be evolved to help make surgical assessments more objective and quantitative. Results: Orthopaedic surgical procedures should benefit from incorporation of methods to measure functional blood perfusion or tissue metabolism. The types of measurements though can vary in the depth of tissue sampled, with some being quite superficial and others sensing several millimeters into the tissue. Most of these intrasurgical imaging tools represent an ideal way to improve surgical treatment of orthopaedic injuries due to their inherent point-of-care use and their compatibility with real-time management. Conclusion: While there are several optical measurements to directly measure bone function, the choice of tools can determine also the signal strength and depth of sampling. For orthopaedic surgery, real-time data regarding bone and tissue perfusion should lead to more effective patient-specific management of common orthopaedic conditions, requiring deeper penetrance commonly seen with indocyanine green imaging. This will lower morbidity and result in decreased variability associated with how these conditions are managed. [ABSTRACT FROM AUTHOR]

Published

2020

47. Intraoperative fluorescence perfusion assessment should be corrected by a measured subject-specific arterial input function.

Author

Elliott, Jonathan T., Addante, Rocco R., Slobogean, Gerard P., Jiang, Shudong, Henderson, Eric R., Pogue, Brian W., and Gitajn, Ida Leah

Subjects

FLUORESCENCE, PERFUSION, INDOCYANINE green, BONES

Abstract

Significance: The effects of varying the indocyanine green injection dose, injection rate, physiologic dispersion of dye, and intravenous tubing volume propagate into the shape and magnitude of the arterial input function (AIF) during intraoperative fluorescence perfusion assessment, thereby altering the observed kinetics of the fluorescence images in vivo. Aim: Numerical simulations are used to demonstrate the effect of AIF on metrics derived from tissue concentration curves such as peak fluorescence, time-to-peak (TTP), and egress slope. Approach: Forward models of tissue concentration were produced by convolving simulated AIFs with the adiabatic approximation to the tissue homogeneity model using input parameters representing six different tissue examples (normal brain, glioma, normal skin, ischemic skin, normal bone, and osteonecrosis). Results: The results show that AIF perturbations result in variations in estimates of total intensity of up to 80% and TTP error of up to 200%, with the errors more dominant in brain, less in skin, and less in bone. Interestingly, error in ingress slope was as high as 60% across all tissue types. These are key observable parameters used in fluorescence imaging either implicitly by viewing the image or explicitly through intensity fitting algorithms. Correcting by deconvolving the image with a measured subject-specific AIF provides an intuitive means of visualizing the data while also removing the source of variance and allowing intra- and intersubject comparisons. Conclusions: These results suggest that intraoperative fluorescence perfusion assessment should be corrected by patient-specific AIFs measured by pulse dye densitometry. [ABSTRACT FROM AUTHOR]

Published

2020

48. Mutual impact of clinically translatable near-infrared dyes on photoacoustic image contrast and in vitro photodynamic therapy efficacy.

Author

Petrovic, Ljubica Z., Xavierselvan, Marvin, Kuriakose, Maju, Kennedy, Michael D., Nguyen, Christopher D., Batt, Julian J., Detels, Kelsey B., and Mallidi, Srivalleesha

Subjects

PHOTODYNAMIC therapy, ACOUSTIC imaging, LIGHT absorption, OPTICAL properties, INDOCYANINE green, PHOTOACOUSTIC spectroscopy

Abstract

Photodynamic therapy (PDT), a spatially localized phototoxic therapy that involves irradiation of a photosensitizer (PS) with specific wavelengths of light, has shown exceptional promise in impacting cancer treatment outcomes, particularly oral cancer. To reduce PDT outcome variability, attempts toward image-guided personalized PDT are being pursued by monitoring PS uptake either via fluorescence or photoacoustic imaging (PAI), a nonionizing modality dependent on optical absorption properties of the tissue. PAI-guided PDT requires a near-infrared contrast agent for deep tissue imaging with minimal photobleaching effect. We evaluate the impact of PDT agent, benzoporphyrin derivative (BPD), on PAI agent indocyanine green (ICG) and vice versa, given that they have different optical absorption properties and singlet oxygen quantum yields for PDT. Specifically, we demonstrate in two oral squamous cell carcinoma lines (FaDu and SCC4) that ICG has minimal effect on BPD PDT efficacy when irradiated with either a continuous or pulsed laser. Furthermore, the impact of BPD on ICG photodegradation was monitored with PAI in tissue-mimicking phantoms. These studies inform us that the combination of BPD and ICG can be utilized for PAI-guided PDT. However, researchers need to consider the photodegradation effects of ICG in the presence of BPD when designing their drug delivery strategies for PAI-guided PDT. [ABSTRACT FROM AUTHOR]

Published

2020

49. Indocyanine green matching phantom for fluorescence-guided surgery imaging system characterization and performance assessment.

Author

Ruiz, Alberto J., Wu, Mindy, LaRochelle, Ethan P. M., Gorpas, Dimitris, Ntziachristos, Vasilis, Pfefer, T. Joshua, and Pogue, Brian W.

Subjects

INDOCYANINE green, IMAGING systems, IMAGING phantoms, MANUFACTURING processes, PRINT materials

Abstract

Significance: Expanded use of fluorescence-guided surgery with devices approved for use with indocyanine green (ICG) has led to a range of commercial systems available. There is a compelling need to be able to independently characterize system performance and allow for cross-system comparisons. Aim: The goal of this work is to expand on previous proposed fluorescence imaging standard designs to develop a long-term stable phantom that spectrally matches ICG characteristics and utilizes 3D printing technology for incorporating tissue-equivalent materials. Approach: A batch of test targets was created to assess ICG concentration sensitivity in the 0.3- to 1000-nM range, tissue-equivalent depth sensitivity down to 6 mm, and spatial resolution with a USAF test chart. Comparisons were completed with a range of systems that have significantly different imaging capabilities and applications, including the Li-Cor® Odyssey, Li-Cor® Pearl, PerkinElmer® Solaris, and Stryker® Spy Elite. Results: Imaging of the ICG-matching phantoms with all four commercially available systems showed the ability to benchmark system performance and allow for cross-system comparisons. The fluorescence tests were able to assess differences in the detectable concentrations of ICG with sensitivity differences >10× for preclinical and clinical systems. Furthermore, the tests successfully assessed system differences in the depth-signal decay rate, as well as resolution performance and image artifacts. The manufacturing variations, photostability, and mechanical design of the tests showed promise in providing long-term stable standards for fluorescence imaging. Conclusions: The presented ICG-matching phantom provides a major step toward standardizing performance characterization and cross-system comparisons for devices approved for use with ICG. The developed hybrid manufacturing platform can incorporate long-term stable fluorescing agents with 3D printed tissue-equivalent material. Further, long-term testing of the phantom and refinements to the manufacturing process are necessary for future implementation as a widely adopted fluorescence imaging standard. [ABSTRACT FROM AUTHOR]

Published

2020

50. Intracranial glioma xenograft model rapidly reestablishes blood–brain barrier integrity for longitudinal imaging of tumor progression using fluorescence molecular tomography and contrast agents.

Author

Habimana-Griffin, LeMoyne, Ye, Dezhuang, Carpenter, Julia, Prior, Julie, Sudlow, Gail, Marsala, Lynne, Mixdorf, Matthew, Rubin, Joshua B., Chen, Hong, and Achilefu, Samuel

Subjects

BLOOD-brain barrier, CANCER invasiveness, BRAIN tumors, FLUORESCENCE, MOLECULAR probes, INTRACRANIAL tumors

Abstract

Significance: The blood–brain barrier (BBB) is a major obstacle to detecting and treating brain tumors. Overcoming this challenge will facilitate the early and accurate detection of brain lesions and guide surgical resection of tumors. Aim: We generated an orthotopic brain tumor model that simulates the pathophysiology of gliomas at early stages; determine the BBB integrity and breakdown over the time course of tumor progression using generic and cancer-targeted near-infrared (NIR) fluorescent molecular probes. Approach: We developed an intracranial tumor xenograft model that rapidly reestablished BBB integrity and monitored tumor progression by bioluminescence imaging. Sham control mice were injected with phosphate-buffered saline only. Fluorescence molecular tomography (FMT) was used to quantify the uptake of tumor-targeted and passive NIR fluorescent imaging agents in orthotopic glioma (U87-GL-GFP PDE7B H217Q cells) tumor model. Cancer-induced and transient (with focused ultrasound, FUS) disruption of BBB integrity was monitored with NIR fluorescent dyes. Results: Stereotactic injection of 50,000 cells into mouse brain allowed rapid reestablishment of BBB integrity within a week, as determined by the inability of both tumor-targeted and generic NIR imaging agents to extravasate into the brain. Tumor-induced BBB disruption was observed 7 weeks after tumor implantation. FUS achieved a similar effect at any time point after reestablishing BBB integrity. While tumor uptake and retention of the passive NIR dye, indocyanine green, was negligible, both actively tumor-targeting agents exhibited selective accumulation in the tumor region. The tumor-targeting molecular probe that clears rapidly from nontumor brain tissue exhibits higher contrast than the analogous vascular-targeting agent and helps delineate tumors from sham control. Conclusions: We highlight the utility of FMT imaging for longitudinal assessment of brain tumors and the interplay between the stages of BBB disruption and molecular probe retention in tumors, with potential application to other neurological diseases. [ABSTRACT FROM AUTHOR]

Published

2020