Exploring uptake mechanisms of oral nanomedicines using multimodal nonlinear optical microscopy

Garrett, Natalie; Lalatsa, Aikaterini; Uchegbu, Ijeoma F.; Schätzlein, Andreas; Moger, Julian

doi:10.1002/jbio.201200006

Cited by 70 publications

(75 citation statements)

References 39 publications

(52 reference statements)

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“…In vivo, fluorescence detection of administered NMs can include not only post-mortem analysis of tissues, but also noninvasive imaging. For example, multimodal multiphoton optical microscopy imaging in mice can qualitatively localize fluorescent NPs such as chitosan in organs (Garrett et al, 2012). X-ray computed tomography and NIR fluorescent imaging can also detect NPs such as fluorescent silica-coated gold nanorods (Luo et al, 2011).…”

Section: Methodological Considerations For Nanomaterials Detection Andmentioning

confidence: 99%

Utility of models of the gastrointestinal tract for assessment of the digestion and absorption of engineered nanomaterials released from food matrices

Venema²,

et al. 2014

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Engineered metal/mineral, lipid and biochemical macromolecule nanomaterials (NMs) have potential applications in food. Methodologies for the assessment of NM digestion and bioavailability in the gastrointestinal tract are nascent and require refinement. A working group was tasked by the International Life Sciences Institute NanoRelease Food Additive project to review existing models of the gastrointestinal tract in health and disease, and the utility of these models for the assessment of the uptake of NMs intended for food. Gastrointestinal digestion and absorption could be addressed in a tiered approach using in silico computational models, in vitro non-cellular fluid systems and in vitro cell culture models, after which the necessity of ex vivo organ culture and in vivo animal studies can be considered. Examples of NM quantification in gastrointestinal tract fluids and tissues are emerging; however, few standardized analytical techniques are available. Coupling of these techniques to gastrointestinal models, along with further standardization, will further strengthen methodologies for risk assessment.

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Section: Methodological Considerations For Nanomaterials Detection Andmentioning

confidence: 99%

Utility of models of the gastrointestinal tract for assessment of the digestion and absorption of engineered nanomaterials released from food matrices

Venema²,

et al. 2014

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“…On the other hand, processes relying on very general optical properties, e.g., refractive index changes in FWM and THG, are powerful for label-free visualization of the overall tissue structure, but provide only unspecific molecular information [19]. Here coherent Raman processes are very powerful enabling both the visualization of the tissue structure, e.g., by utilizing abundant vibrational resonances for imaging, but also highly selective visualization, when a molecule or structure specific vibrational resonance is probed, e.g., for drug delivery studies with isotope labeling [28,29].…”

Section: Methodsmentioning

confidence: 99%

“…All these exogenous labels generate significantly brighter nonlinear signals than endogenous molecular markers, which is key for increasing the image acquisition or allows detecting very low concentrations of marker molecules. For CRS based techniques, isotope labelling with deuterium shifts the signal to a silent region of the vibrational spectrum, allowing for drug delivery investigations [28,29]. Alternatively the high specificity of antibodies routinely used in immunohistochemistry can be combined with vibrational detection.…”

Section: Labelingmentioning

confidence: 99%

“…The visualization Figure 5 Multimodal nonlinear microscopy for imaging of tissue structure and composition. (A) the uptake of deuterated nanoparticles is monitored by CARS microscopy (2100 cm À1 , green) while the tissue is depicted by 2PF, red, autofluorescence, GC-goblet cell [28]. (B) engineered tissue made of cellulose fibers (blue, SHG) is seeded with smooth muscle cells (CARS 2845 cm À1 , yellow), which develop into different cell phenotypes (1, 2) and produce collagen as an extracellular matrix element by themselves (2, arrow) [109].…”

Section: Structural Imaging Of Cells Tissues and Diseasesmentioning

confidence: 99%

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Accumulating advantages, reducing limitations: Multimodal nonlinear imaging in biomedical sciences – The synergy of multiple contrast mechanisms

Meyer

Schmitt

Dietzek

et al. 2013

Journal of Biophotonics

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Journal of BIOPHOTONICSMultimodal nonlinear microscopy has matured during the past decades to one of the key imaging modalities in life science and biomedicine due to its unique capabilities of label-free visualization of tissue structure and chemical composition, high depth penetration, intrinsic 3D sectioning, diffraction limited resolution and low phototoxicity. This review briefly summarizes first recent advances in the field regarding the methodology, e.g., contrast mechanisms and signal characteristics used for contrast generation as well as novel image processing approaches. The second part deals with technologic developments emphasizing improvements in penetration depth, imaging speed, spatial resolution and nonlinear labeling strategies. The third part focuses on recent applications in life science fundamental research and biomedical diagnostics as well as future clinical applications.Multimodal nonlinear microscopy of tissue.

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“…Furthermore, an emerging area of applications for CARS microscopy is the imaging of drugs and drug delivery. Apart from being able to track penetrating oil-rich ointments applied to skin [17] CARS has also been used to track deuterated drug particles in mouse tissue [18].…”

Section: Introductionmentioning

confidence: 99%

CARS based label‐free assay for assessment of drugs by monitoring lipid droplets in tumour cells

Steuwe

Patel

Ul-Hasan

et al. 2013

Journal of Biophotonics

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Coherent anti-Stokes Raman scattering (CARS) is becoming an established tool for label-free multi-photon imaging based on molecule specific vibrations in the sample. The technique has proven to be particularly useful for imaging lipids, which are abundant in cells and tissues, including cytoplasmic lipid droplets (LD), which are recognized as dynamic organelles involved in many cellular functions. The increase in the number of lipid droplets in cells undergoing cell proliferation is a common feature in many neoplastic processes [1] and an increase in LD number also appears to be an early marker of drug-induced cell stress and subsequent apoptosis [3]. In this paper, a CARS-based label-free method is presented to monitor the increase in LD content in HCT116 colon tumour cells treated with the chemotherapeutic drugs Etoposide, Camptothecin and the protein kinase inhibitor Staurosporine. Using CARS, LDs can easily be distinguished from other cell components without the application of fluorescent dyes and provides a label-free noninvasive drug screening assay that could be used not only with cells and tissues ex vivo but potentially also in vivo.Series of CARS images of HCT 116 cells after treatment at the specified times after drug treatment.

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Exploring uptake mechanisms of oral nanomedicines using multimodal nonlinear optical microscopy

Cited by 70 publications

References 39 publications

Utility of models of the gastrointestinal tract for assessment of the digestion and absorption of engineered nanomaterials released from food matrices

Utility of models of the gastrointestinal tract for assessment of the digestion and absorption of engineered nanomaterials released from food matrices

Accumulating advantages, reducing limitations: Multimodal nonlinear imaging in biomedical sciences – The synergy of multiple contrast mechanisms

CARS based label‐free assay for assessment of drugs by monitoring lipid droplets in tumour cells

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