Non-invasive monitoring of pharmacodynamics during the skin wound healing process using multimodal optical microscopy

ObjectiveImpaired diabetic wound healing is one of the serious complications associated with diabetes. In patients with diabetes, this impairment is characterized by several physiological abnormalities such as metabolic changes, reduced collagen production, and diminished angiogenesis. We designed a...

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Published in:BMJ open diabetes research & care 2020-04, Vol.8 (1), p.e000974
Main Authors: Rico-Jimenez, Jose, Lee, Jang Hyuk, Alex, Aneesh, Musaad, Salma, Chaney, Eric, Barkalifa, Ronit, Spillman Jr, Darold R, Olson, Eric, Adams, David, Marjanovic, Marina, Arp, Zane, Boppart, Stephen A
Format: Article
Language:English
Subjects:
Angiogenesis
Animals
Cameras
Cell adhesion & migration
Collagen
Diabetes
Diabetes Mellitus, Type 2
Emerging Technologies, Pharmacology and Therapeutics
Hair
Humans
Investigations
Laboratory animals
Lasers
Light
Medical imaging
Metabolism
Mice
Microscopy
Pharmacodynamics
Physiology
Skin
Skin - diagnostic imaging
Wound Healing
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Summary:ObjectiveImpaired diabetic wound healing is one of the serious complications associated with diabetes. In patients with diabetes, this impairment is characterized by several physiological abnormalities such as metabolic changes, reduced collagen production, and diminished angiogenesis. We designed and developed a multimodal optical imaging system that can longitudinally monitor formation of new blood vessels, metabolic changes, and collagen deposition in a non-invasive, label-free manner.Research design and methodsThe closure of a skin wound in (db/db) mice, which presents delayed wound healing pathologically similar to conditions in human type 2 diabetes mellitus, was non-invasively followed using the custom-built multimodal microscope. In this microscope, optical coherence tomography angiography was used for studying neovascularization, fluorescence lifetime imaging microscopy for nicotinamide adenine dinucleotide (phosphate) (NAD(P)H) assessment, fluorescence intensity changes of NAD(P)H and flavin adenine dinucleotide (FAD) cofactors for evaluating metabolic changes, and second harmonic generation microscopy for analyzing collagen deposition and organization. The animals were separated into four groups: control, placebo, low concentration (LC), and high concentration (HC) treatment. Images of the wound and surrounding areas were acquired at different time points during a 28-day period.ResultsVarious physiological changes measured using the optical imaging modalities at different phases of wound healing were compared. A statistically significant improvement in the functional relationship between angiogenesis, metabolism, and structural integrity was observed in the HC group.ConclusionsThis study demonstrated the capability of multimodal optical imaging to non-invasively monitor various physiological aspects of the wound healing process, and thus become a promising tool in the development of better diagnostic, treatment, and monitoring strategies for diabetic wound care.
ISSN:2052-4897
2052-4897
DOI:10.1136/bmjdrc-2019-000974