TY - JOUR
T1 - Extracellular matrix remodeling of lung alveolar walls in three dimensional space identified using second harmonic generation and multiphoton excitation fluorescence
AU - Abraham, Thomas
AU - Hogg, James
N1 - Funding Information:
Images were generated and processed at the Cellular Imaging and Biophysics Core Facility at the James Hogg Research Centre, The University of British Columbia – St. Paul’s Hospital, an imaging facility created from Canada Foundation for Innovation funds. T.A. acknowledges financial support from the St. Paul’s Hospital during the course of this work. Authors thank Dr. Joel Cooper, Chief of the Department of Thoracic Surgery at the University of Pennsylvania for providing the lung tissue specimens and Dr. Mark Elliott for providing biobanking services. Authors also thank John Gosslink, Drs. Darryl Knight, Samuel Wadsworth for insightful comments, and Dr. Alex Scott (Centre for Hip Health and Mobility) for the critical reading of this manuscript and his constructive suggestions.
PY - 2010/8
Y1 - 2010/8
N2 - The structural reorganization of extracellular matrix (ECM) is an important feature of peripheral lung tissue remodeling in chronic obstructive pulmonary disease (COPD). Ordered ECM macromolecules such as the fibril-forming collagens produce second harmonic generation (SHG) signal without the need for any exogenous label, while ECM macromolecules such as the elastin fibers generate MPEF signal due to their endogenous fluorescence characteristics. Both these signals can be captured simultaneously to provide spatially resolved 3D structural reorganization of ECM matrix. In this study, SHG and MPEF microscopy methods were used to examine structural remodeling of the ECM matrix in human lung alveolar walls undergoing severe emphysematous destruction. Flash frozen lung samples removed from two patients undergoing lung transplantation for severe COPD (n= 4) were compared to similar samples from an unused donor lung (n= 2) that served as a control. The imaging operations were performed directly on these tissue sections at least three different areas. The generated spatially resolved 3D images showed the distribution of collagen and elastin in the alveolar walls. In the case of the control, we found well ordered alveolar walls with a composite type structure made up of collagen bands and relatively fine elastic fibers. In contrast, lung tissues undergoing emphysematous destruction were highly disorganized with significantly increased alveolar wall thickness compared to the control. We conclude that these non-invasive imaging modalities provide spatially resolved 3D images with spectral specificities that are sensitive enough to identity the ECM structural changes associated with emphysematous destruction.
AB - The structural reorganization of extracellular matrix (ECM) is an important feature of peripheral lung tissue remodeling in chronic obstructive pulmonary disease (COPD). Ordered ECM macromolecules such as the fibril-forming collagens produce second harmonic generation (SHG) signal without the need for any exogenous label, while ECM macromolecules such as the elastin fibers generate MPEF signal due to their endogenous fluorescence characteristics. Both these signals can be captured simultaneously to provide spatially resolved 3D structural reorganization of ECM matrix. In this study, SHG and MPEF microscopy methods were used to examine structural remodeling of the ECM matrix in human lung alveolar walls undergoing severe emphysematous destruction. Flash frozen lung samples removed from two patients undergoing lung transplantation for severe COPD (n= 4) were compared to similar samples from an unused donor lung (n= 2) that served as a control. The imaging operations were performed directly on these tissue sections at least three different areas. The generated spatially resolved 3D images showed the distribution of collagen and elastin in the alveolar walls. In the case of the control, we found well ordered alveolar walls with a composite type structure made up of collagen bands and relatively fine elastic fibers. In contrast, lung tissues undergoing emphysematous destruction were highly disorganized with significantly increased alveolar wall thickness compared to the control. We conclude that these non-invasive imaging modalities provide spatially resolved 3D images with spectral specificities that are sensitive enough to identity the ECM structural changes associated with emphysematous destruction.
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U2 - 10.1016/j.jsb.2010.04.006
DO - 10.1016/j.jsb.2010.04.006
M3 - Article
C2 - 20412859
AN - SCOPUS:77953726532
SN - 1047-8477
VL - 171
SP - 189
EP - 196
JO - Journal of Structural Biology
JF - Journal of Structural Biology
IS - 2
ER -