Research about the cutaneous burn was separated by assessment of burn depth and development of wound healing therapy. Various in vivo optical techniques were used to determined burn depth and observe the wound healing process. In this paper, we report the usage of multimodal optical coherence tomography system, which containing angiographic and polarization sensitive OCT (PS-OCT) with conventional OCT system, at burn studies. Burn was induced at 4 different degrees by control the attachment time of 75 Celsius degree heated brass rod at dorsal skin of the rat. For the burn depth assessment, we imaged the different burn degrees area. Changes of polarization sensitive signal were providing burn depth information. To see the wound healing process, each wound area imaged at long period. Conventional OCT shows the structural information about the tissue, like layer and hair follicle. Angiographic OCT provides vascular distribution and diameter of blood vessel information and PS-OCT shows birefringence tissue information. Based on the multimodal OCT data, burn depth assessment were well matched with burn induced time and wound healing process was consistent with previous wound healing report. Therefore, the multimodal OCT holds potential for burn study.
A combined two-photon microscopy (TPM) and angiographic optical coherence tomography (OCT) is developed, which can provide molecular, cellular, structural, and vascular information of tissue specimens in vivo. This combined system is implemented by adding an OCT vasculature visualization method to the previous combined TPM and OCT, and then is applied to in vivo tissue imaging. Two animal models, a mouse brain cranial window model and a mouse ear cancer model, are used. Both molecular, cellular information at local regions of tissues, and structural, vascular information at relatively larger regions are visualized in the same sections. In vivo tissue microenvironments are better elucidated by the combined TPM and angiographic OCT.