Nonstaining Blood Flow Imaging Using Optical Interference Due to Doppler Shift and Near-Infrared Imaging of Molecular Distribution in Developing Fish Egg Embryos.
Mika IshigakiParalee PuangchitYui YasuiAkane IshidaHiroki HayashiYoshihiko NakayamaHideya TaniguchiIchiro IshimaruYukihiro OzakiPublished in: Analytical chemistry (2018)
In the present study, we successfully obtained nonstaining blood flow images of a developing fish egg embryo using optical interference caused by the Doppler shift. The spectral distribution of light reflected by moving objects such as the heart and red cells was found to be different from that of the incident light because of the Doppler effect. Interference between different frequency components was observed in an interferogram through heterodyne interaction using an imaging-type two-dimensional Fourier spectroscopic system, and information on the intensities of the spectral components was obtained by Fourier transformation. Beat signals with specific frequencies due to the heart beating and blood flow of the fish egg embryo were detected. When the signals were plotted in two dimensions, the heart part and vessel flows were clearly visualized without staining. In addition, near-infrared (NIR) images were produced using absorbance spectra of the molecular vibrations of O-H and C-H groups included in water, hydrocarbons, and aliphatic compounds. Obtaining nonstaining blood flow images using heterodyne optical interference and images of molecular distribution using molecular vibrational information simultaneously manifests an exciting advance in NIR imaging.
Keyphrases
- blood flow
- high resolution
- optical coherence tomography
- deep learning
- convolutional neural network
- fluorescence imaging
- heart failure
- photodynamic therapy
- atrial fibrillation
- single molecule
- cardiovascular disease
- high speed
- healthcare
- magnetic resonance imaging
- mass spectrometry
- signaling pathway
- molecular dynamics simulations
- social media
- molecular dynamics
- machine learning
- raman spectroscopy
- pi k akt