FMT-XCT: in vivo animal studies with hybrid fluorescence molecular tomography–X-ray computed tomography

Ale, Angelique; Ermolayev, Vladimir; Herzog, Eva; Cohrs, Christian M.; Angelis, Martin Hrabé de; Ntziachristos, Vasilis

doi:10.1038/nmeth.2014

Cited by 244 publications

(157 citation statements)

References 37 publications

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“…To address the shortcomings associated with standard FMT, we (and others) have developed protocols for the co-registration of CT and FMT data sets [30][31][32]. The advantage of such co-registered images is the addition of anatomical information, allowing for a much more precise 3D segmentation of tumors (and other organs of interest) on the basis of the CT images, yielding a highly reproducible method for biodistribution analyses [32].…”

Section: Optical Imaging Of Epr-mediated Passive Drug Targetingmentioning

confidence: 99%

“…We here used ~70 kDa-sized near-infrared fluorophore (NIRF) -labeled HPMA copolymers (which are known to efficiently accumulate in subcutaneous CT26 tumors in mice via EPR [29]), hybrid computed tomography-fluorescence molecular tomography (CT-FMT; [30][31][32]) and microbubble (MB) -based contrast-enhanced functional ultrasound (ceUS) imaging [33,34], to demonstrate that the degree of tumor vascularization correlates with the degree of EPR-mediated passive drug targeting. These findings indicate that relatively easily imageable vascular parameters, such as tumor blood volume and tumor blood flow, can be used to characterize EPR, and to on the basis of this preselect patients likely to respond to passively tumor-targeted nanomedicine therapies.…”

Section: Introductionmentioning

confidence: 99%

“…Clinically, however, due to the abovementioned large inter-and intraindividual variability in EPR, the efficacy of passively tumor-targeted nanomedicines is compromised, with often significant improvements in tolerability, but hardly any increases in efficacy [9,10,14]. Consequently, there seems to be a clear need to develop methods to visualize and characterize the EPR effect, in order to preselect patients presenting with sufficiently high levels of EPR, to thereby (pre-) stratify responders and non-responders, and to thereby individualize and improve nano-chemotherapeutic treatments.We here used ~70 kDa-sized near-infrared fluorophore (NIRF) -labeled HPMA copolymers (which are known to efficiently accumulate in subcutaneous CT26 tumors in mice via EPR [29]), hybrid computed tomography-fluorescence molecular tomography (CT-FMT; [30][31][32]) and microbubble (MB) -based contrast-enhanced functional ultrasound (ceUS) imaging [33,34], to demonstrate that the degree of tumor vascularization correlates with the degree of EPR-mediated passive drug targeting. These findings indicate that relatively easily imageable vascular parameters, such as tumor blood volume and tumor blood flow, can be used to characterize EPR, and to on the basis of this preselect patients likely to respond to passively tumor-targeted nanomedicine therapies.…”

mentioning

confidence: 99%

“…Depth cannot be determined, and has to be estimated on the basis of the FMT signal. This approach consequently results in a relatively subjective interpretation of the data, and may give rise to biased, inaccurate and/or incorrect outcomes (depending on the observer's experience, expertise and expectations).To address the shortcomings associated with standard FMT, we (and others) have developed protocols for the co-registration of CT and FMT data sets [30][31][32]. The advantage of such co-registered images is the addition of anatomical information, allowing for a much more precise 3D segmentation of tumors (and other organs of interest) on the basis of the CT images, yielding a highly reproducible method for biodistribution analyses [32].…”

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confidence: 99%

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Characterizing EPR-mediated passive drug targeting using contrast-enhanced functional ultrasound imaging

Theek

Gremse

Kunjachan

et al. 2014

Journal of Controlled Release

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The Enhanced Permeability and Retention (EPR) effect is extensively used in drug delivery research. Taking into account that EPR is a highly variable phenomenon, we have here set out to evaluate if contrast-enhanced functional ultrasound (ceUS) imaging can be employed to characterize EPR-mediated passive drug targeting to tumors. Using standard fluorescence molecular tomography (FMT) and two different protocols for hybrid computed tomographyfluorescence molecular tomography (CT-FMT), the tumor accumulation of a ~10 nm-sized nearinfrared-fluorophore-labeled polymeric drug carrier (pHPMA-Dy750) was evaluated in CT26 tumor-bearing mice. In the same set of animals, two different ceUS techniques (2D MIOT and 3D B-mode imaging) were employed to assess tumor vascularization. Subsequently, the degree of tumor vascularization was correlated with the degree of EPR-mediated drug targeting. Depending on the optical imaging protocol used, the tumor accumulation of the polymeric drug carrier ranged from 5-12% of the injected dose. The degree of tumor vascularization, determined using ceUS, varied from 4-11%. For both hybrid CT-FMT protocols, a good correlation between the degree of tumor vascularization and the degree of tumor accumulation was observed, with in the case of reconstructed CT-FMT, correlation coefficients of ~0.8 and p-values of <0.02. These findings indicate that ceUS can be used to characterize and predict EPR, and potentially also to preselecting patients likely to respond to passively tumor-targeted nanomedicine treatments. KeywordsDrug targeting; Nanomedicine; Theranostics; Cancer; EPR; HPMA; US; FMT; CT The biodistribution of nanomedicine formulations is very different from that of lowmolecular-weight drugs. As the size of nanocarrier materials generally is above the kidney clearance threshold (~5 nm), they tend to circulate for prolonged periods of time, and they are consequently able to exploit the fact that tumor blood vessels are more leaky that healthy blood vessels, resulting in passive, progressive and relatively selective accumulation at the pathological site over time. This phenomenon is known as the Enhanced Permeability and Retention (EPR) effect [7,8], and it is extensively used in drug delivery research. It is increasingly recognized, however, that EPR is a highly variably phenomenon, presenting not only with large differences between different animal models and patient tumors, but also with large inter-and intraindividual differences between tumors of the same sub-type. And even within a single tumor, certain vessels are significantly more leaky than others. Several recent reviews critically describe and comprehensively discuss the validity and the variability of the EPR effect [9][10][11][12][13][14]. To better understand EPR, to predict which animal models or patient tumors are likely to benefit from EPR-mediated passive drug targeting, and to thereby individualize and improve nano-chemotherapeutic treatments, it therefore seems highly important to identify imageable parameters to c...

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Section: Optical Imaging Of Epr-mediated Passive Drug Targetingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Characterizing EPR-mediated passive drug targeting using contrast-enhanced functional ultrasound imaging

Theek

Gremse

Kunjachan

et al. 2014

Journal of Controlled Release

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“…In contrast to non-invasive microscopy techniques, which allow imaging of superficial targets at subcellular resolution 1 , FMT allows three-dimensional reconstruction of fluorescent sources in depths of several centimeters, albeit at lower resolution 2 . Many targeted fluorescent probes are available to image angiogenesis, apoptosis, inflammation, and others [2][3][4][5] . Some probes are activatable, e.g., by specific enzyme cleavage leading to unquenching of fluorochromes.…”

Section: Introductionmentioning

confidence: 99%

Hybrid µCT-FMT imaging and image analysis

Gremse

Doleschel

Zafarnia

et al. 2015

JoVE

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Fluorescence-mediated tomography (FMT) enables longitudinal and quantitative determination of the fluorescence distribution in vivo and can be used to assess the biodistribution of novel probes and to assess disease progression using established molecular probes or reporter genes. The combination with an anatomical modality, e.g., micro computed tomography (µCT), is beneficial for image analysis and for fluorescence reconstruction. We describe a protocol for multimodal µCT-FMT imaging including the image processing steps necessary to extract quantitative measurements. After preparing the mice and performing the imaging, the multimodal data sets are registered. Subsequently, an improved fluorescence reconstruction is performed, which takes into account the shape of the mouse. For quantitative analysis, organ segmentations are generated based on the anatomical data using our interactive segmentation tool. Finally, the biodistribution curves are generated using a batchprocessing feature. We show the applicability of the method by assessing the biodistribution of a well-known probe that binds to bones and joints.

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In Vivo Fluorescence Imaging

Lin¹,

Liu²,

Quiroz³

2022

Encyclopedia of Analytical Chemistry

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In vivo fluorescence imaging is an essential tool for many biomedical researches and clinical applications. It provides intuitive, direct evidence to help researchers understand complicated biological phenomena and clinicians to make better decisions. In this article, we will introduce important tissue optical properties that determine the performance of in vivo fluorescence images. Besides the biological specimen itself, imaging methods and fluorophores are the two key components that determine its performance and capabilities. Several types of imaging methods, suitable cameras, and the currently available fluorophores will be described. In the last section, we focus on the clinical applications, mainly image‐guided surgeries. The future development of in vivo fluorescence imaging tackles the challenge of deep tissue imaging, and short‐wave infrared fluorescence will be our new solution. Therefore, we will also comment on the recent developments of SWIR techniques in each topic discussed.

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FMT-XCT: in vivo animal studies with hybrid fluorescence molecular tomography–X-ray computed tomography

Cited by 244 publications

References 37 publications

Characterizing EPR-mediated passive drug targeting using contrast-enhanced functional ultrasound imaging

Characterizing EPR-mediated passive drug targeting using contrast-enhanced functional ultrasound imaging

Hybrid µCT-FMT imaging and image analysis

In Vivo Fluorescence Imaging

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FMT-XCT: in vivo animal studies with hybrid fluorescence molecular tomography–X-ray computed tomography

Cited by 244 publications

References 37 publications

Characterizing EPR-mediated passive drug targeting using contrast-enhanced functional ultrasound imaging

Characterizing EPR-mediated passive drug targeting using contrast-enhanced functional ultrasound imaging

Hybrid &#181;CT-FMT imaging and image analysis

In Vivo Fluorescence Imaging

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Hybrid µCT-FMT imaging and image analysis