Sensors for Proteolytic Activity Visualization and Their Application in Animal Models of Human Diseases

Various sensors designed for optical and photo(opto)acoustic imaging in living systems are becoming essential components of basic and applied biomedical research. Some of them including those developed for determining enzyme activity in vivo are becoming commercially available. These sensors can be...

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Bibliographic Details
Published in:Biochemistry (Moscow) 2019, Vol.84 (Suppl 1), p.1-18
Main Authors: Bogdanov, A. A., Solovyev, I. D., Savitsky, A. P.
Format: Article
Language:English
Subjects:
Acoustic imaging
Amino acids
Animal diseases
Animal models
Animals
Biochemistry
Biocompatibility
Biomedical and Life Sciences
Biomedical materials
Biomedicine
Bioorganic Chemistry
Biosensing Techniques - methods
Cameras
Chemical compounds
Detectors
Disease Models, Animal
Diseases
Early Diagnosis
Endoscopy
Enzymatic activity
Enzyme activity
Enzymes
Fluorescence
Fluorescent Dyes - chemistry
Fluorescent indicators
Fluorophores
Humans
Immunogenicity
In vivo methods and tests
Life Sciences
Macromolecules
Medical imaging
Medical research
Medicine, Experimental
Methylene blue
Microbiology
Optical communication
Optical Imaging - methods
Peptide Hydrolases - metabolism
Probes
Proteolysis
Review
Sensors
Signal detection
Signal detectors
Spectral sensitivity
Toxicity
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Description
Summary:Various sensors designed for optical and photo(opto)acoustic imaging in living systems are becoming essential components of basic and applied biomedical research. Some of them including those developed for determining enzyme activity in vivo are becoming commercially available. These sensors can be used for various fluorescent signal detection methods: from whole body tomography to endoscopy with miniature cameras. Sensor molecules including enzyme-cleavable macromolecules carrying multiple quenched near-infrared fluorophores are able to deliver their payload in vivo and have long circulation time in bloodstream enabling detection of enzyme activity for extended periods of time at low doses of these sensors. In the future, more effective “activated” probes are expected to become available with optimized sensitivity to enzymatic activity, spectral characteristics suitable for intraoperative imaging of surgical field, biocompatibility and lack of immunogenicity and toxicity. New in vivo optical imaging methods such as the fluorescence lifetime and photo(opto)acoustic imaging will contribute to early diagnosis of human diseases. The use of sensors for in vivo optical imaging will include more extensive preclinical applications of experimental therapies. At the same time, the ongoing development and improvement of optical signal detectors as well as the availability of biologically inert and highly specific fluorescent probes will further contribute to the introduction of fluorescence imaging into the clinic.
ISSN:0006-2979
1608-3040
DOI:10.1134/S0006297919140013