In vivo mouse fluorescence imaging for folate-targeted delivery and release kinetics

Tsai, Esther H. R.; Bentz, Brian Z.; Chelvam, Venkatesh; Gaind, Vaibhav; Webb, Kevin J.; Low, Philip S.

doi:10.1364/boe.5.002662

Cited by 18 publications

(12 citation statements)

References 42 publications

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“…Data were captured from the printed mice for reconstruction using an automated version of the measurement setup we have used previously for live mouse imaging [6]. The setup is shown in Fig.…”

Section: Methodsmentioning

confidence: 99%

“…An unstructured finite element mesh was generated using TetGen [32] using 22,489 nodes (4881 surface nodes) from a subset of the Digimouse data. Alternatively, the 3D line scan could have been used to generate the mesh, as we have done previously for imaging mice where the 3D surface profile is not known [6,27], however, the mesh generated from the Digimouse data is more accurate as it was used to print the mouse. For reconstruction, images were formed on a Cartesian grid with voxel size (1 mm) 3 and a nonlinear conjugate gradient iterative solver was used with first-order Tikhonov regularization.…”

Section: Optical Imaging Of Printed Mouse Phantomsmentioning

confidence: 99%

“…A rich spectrum of methods relying on the coherent or incoherent properties of light have been developed for applications ranging from focusing light through scatter [1–3] to protein folding and anticancer drug pharmacokinetics studies [4–6] to brain imaging [7–9]. The great challenge for these methods is overcoming the deleterious effects of scatter and absorption, which randomize the propagation direction of light and tend to decrease image resolution and quality.…”

Section: Introductionmentioning

confidence: 99%

“…In contrast, the phantoms fabricated here are for deep tissue ( > 2 cm depth, the location of major organs) imaging and the development of diffuse optical tomography (DOT) [15–18]. DOT is a whole animal optical imaging modality, allowing, for example, the determination of tumor sizes and locations [19], pharmacokinetic rates [6], and whole brain activation maps [20]. We note, however, that there is copious room to explore the uses of 3D printing for other imaging methods.…”

Section: Introductionmentioning

confidence: 99%

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Fabrication and application of heterogeneous printed mouse phantoms for whole animal optical imaging

et al. 2016

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This work demonstrates the usefulness of 3D printing for optical imaging applications. Progress in developing optical imaging for biomedical applications requires customizable and often complex objects for testing and evaluation. There is therefore high demand for what have become known as tissue-simulating “phantoms.” We present a new optical phantom fabricated using inexpensive 3D printing methods with multiple materials, allowing for the placement of complex inhomogeneities in complex or anatomically realistic geometries, as opposed to previous phantoms, which were limited to simple shapes formed by molds or machining. We use diffuse optical imaging to reconstruct optical parameters in 3D space within a printed mouse to show the applicability of the phantoms for developing whole animal optical imaging methods. This phantom fabrication approach is versatile, can be applied to optical imaging methods besides diffusive imaging, and can be used in the calibration of live animal imaging data.

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Section: Methodsmentioning

confidence: 99%

Section: Optical Imaging Of Printed Mouse Phantomsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fabrication and application of heterogeneous printed mouse phantoms for whole animal optical imaging

et al. 2016

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“…Instrumentation for DOI is typically inexpensive and safe, and related technology has been used to develop the highly successful pulse oximetry devices [3]. In DOI methods such as diffuse optical tomography (DOT), near-infrared or visible light is used to form volumetric images in deep (>1 cm) tissue by treating photons as diffusing particles [4–6]. However, this is a computationally intensive process, limiting its application in surgery, where information is often needed in real time.…”

Section: Introductionmentioning

confidence: 99%

Diffuse optical localization of blood vessels and 3D printing for guiding oral surgery

Bentz

Wu²,

Gaind

et al. 2017

Appl. Opt.

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Diffuse optical imaging through centimeters of tissue has emerged as a powerful tool in biomedical research. However, applications in the operating theater have been limited in part due to data set requirements and computational burden. We present an approach that uses a small number of optical source-detector pairs that allows for the fast localization of arteries in the roof of the mouth and has the potential to reduce complications during oral surgery. The arteries are modeled as multiple-point absorbers, allowing localization of their complex shapes. The method is demonstrated using a printed tissue-simulating mouth phantom. Furthermore, we use the extracted position information to fabricate a custom surgical guide using 3D printing that could protect the arteries during surgery.

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Quantitative imaging of receptor-ligand engagement in intact live animals

Rudkouskaya

Sinsuebphon

Ward

et al. 2018

Journal of Controlled Release

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Maintaining an intact tumor environment is critical for quantitation of receptor-ligand engagement in a targeted drug development pipeline. However, measuring receptor-ligand engagement in vivo and non-invasively in preclinical settings is extremely challenging. We found that quantitation of intracellular receptor-ligand binding can be achieved using whole-body macroscopic lifetime-based Förster Resonance Energy Transfer (FRET) imaging in intact, live animals bearing tumor xenografts. We determined that FRET levels report on ligand binding to transferrin receptors conversely to raw fluorescence intensity. FRET levels in heterogeneous tumors correlate with intracellular ligand binding but strikingly, not with ubiquitously used ex vivo receptor expression assessment. Hence, MFLI-FRET provides a direct measurement of systemic delivery, target availability and intracellular drug delivery in preclinical studies. Here, we have used MFLI to measure FRET longitudinally in intact and live animals. MFLI-FRET is well-suited for guiding the development of targeted drug therapy in heterogeneous tumors in intact, live small animals.

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In vivo mouse fluorescence imaging for folate-targeted delivery and release kinetics

Cited by 18 publications

References 42 publications

Fabrication and application of heterogeneous printed mouse phantoms for whole animal optical imaging

Fabrication and application of heterogeneous printed mouse phantoms for whole animal optical imaging

Diffuse optical localization of blood vessels and 3D printing for guiding oral surgery

Quantitative imaging of receptor-ligand engagement in intact live animals

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