Feasibility study of incident dark-field video microscope for measuring microcirculatory variables in the mouse dorsal skinfold chamber model

• Published in: Acute and critical care Vol. 36; no. 1; pp. 29 - 36
• Main Authors: Kang, Christine, Cho, Ah-Reum, Lee, Hyeon Jeong, Kim, Hyae Jin, Kim, Eun-Jung, Jeo, Soeun, Hong, Jeong-Min, Moon, Daehoan
• Format: Journal Article
• Language: English
• Published: Korea (South) Korean Society of Critical Care Medicine 01.02.2021; 대한중환자의학회
• Subjects: dorsal skinfold chamber model; glycocalyx; incident dark field; microcirculation; Original; sepsis; 마취과학; glycocalyx; incident dark field; dorsal skinfold chamber model; microcirculation; sepsis
• ISSN: 2586-6052; 2586-6060; 2586-6060
• DOI: 10.4266/acc.2020.00969

Despite the importance of microcirculation in organ function, monitoring microcirculation is not a routine practice. With developments in microscopic technology, incident dark field (IDF) microscopy (Cytocam) has allowed visualization of the microcirculation. Dorsal skinfold chamber (DSC) mouse model has been used to investigate microcirculation physiology. By employing Cytocam-IDF imaging with DSC model to assess microcirculatory alteration in lipopolysaccharide (LPS)-induced endotoxemia, we attempted to validate availability of Cytocam-IDF imaging of microcirculation. DSC was implanted in eight BALB/c mice for each group; control and sepsis. Both groups were given 72 hours to recover from surgery. The sepsis group had an additional 24-hour period of recovery post-LPS injection (4 mg/kg). Subsequently, a video of the microcirculation was recorded using Cytocam. Data on microcirculatory variables were obtained. Electron microscopy was implemented using lanthanum fixation to detect endothelial glycocalyx degradation. The microcirculatory flow index was significantly lower (control, 2.8±0.3; sepsis, 2.1±0.8; P=0.033) and heterogeneity index was considerably higher (control, 0.10±0.15; sepsis, 0.53±0.48; P=0.044) in the sepsis group than in the control group. Electron microscopy revealed glycocalyx demolishment in the sepsis group. Cytocam showed reliable ability for observing changes in the microcirculation under septic conditions in the DSC model. The convenience and good imaging quality and the automatic analysis software available for Cytocam-IDF imaging, along with the ability to perform real-time in vivo experiments in the DSC model, are expected to be helpful in future microcirculation investigations.