![]() | Up a level |
This graph maps the connections between all the collaborators of {}'s publications listed on this page.
Each link represents a collaboration on the same publication. The thickness of the link represents the number of collaborations.
Use the mouse wheel or scroll gestures to zoom into the graph.
You can click on the nodes and links to highlight them and move the nodes by dragging them.
Hold down the "Ctrl" key or the "⌘" key while clicking on the nodes to open the list of this person's publications.
A word cloud is a visual representation of the most frequently used words in a text or a set of texts. The words appear in different sizes, with the size of each word being proportional to its frequency of occurrence in the text. The more frequently a word is used, the larger it appears in the word cloud. This technique allows for a quick visualization of the most important themes and concepts in a text.
In the context of this page, the word cloud was generated from the publications of the author {}. The words in this cloud come from the titles, abstracts, and keywords of the author's articles and research papers. By analyzing this word cloud, you can get an overview of the most recurring and significant topics and research areas in the author's work.
The word cloud is a useful tool for identifying trends and main themes in a corpus of texts, thus facilitating the understanding and analysis of content in a visual and intuitive way.
Amini, S., Mortazavi, F., Sun, J., Lévesque, M., Hoemann, C. D., & Villemure, I. (2013). Stress relaxation of swine growth plate in semi-confined compression: Depth dependent tissue deformational behavior versus extracellular matrix composition and collagen fiber organization. Biomechanics and Modeling in Mechanobiology, 12(1), 67-78. External link
Chen, H., Chevrier, A., Hoemann, C. D., Sun, J., Ouyang, W., & Buschmann, M. D. (2011). Characterization of subchondral bone repair for marrow-stimulated chondral defects and its relationship to articular cartilage resurfacing. American Journal of Sports Medicine, 39(8), 1731-1730. External link
Chen, H., Hoemann, C. D., Sun, J., Chevrier, A., McKee, M. D., Shive, M. S., Hurtig, M., & Buschmann, M. D. (2011). Depth and type of subchondral perforation influence the outcome of bone marrow stimulation cartilage repair. Journal orthopaedic research, 29(8), 1178-1184. External link
Chen, H., Sun, J., Hoemann, C. D., Lascau-Coman, V., Ouyang, W., McKee, M. D., Shive, M. S., & Buschmann, M. D. (2009). Drilling and Microfracture Lead to Different Bone Structure and Necrosis During Bone-Marrow Stimulation for Cartilage Repair. Journal of Orthopaedic Research, 27(11), 1432-1438. External link
Chevrier, A., Hoemann, C. D., Sun, J., & Buschmann, M. D. (2007). Chitosan-Glycerol Phosphate/Blood Implants Increase Cell Recruitment, Transient Vascularization and Subchondral Bone Remodeling in Drilled Cartilage Defects. Osteoarthritis and Cartilage, 15(3), 316-327. External link
Hoemann, C. D., Sun, J., Hurtig, M., Guzman-Morales, J., & Hubert-Lafantaisie, C. (2011). Presolidified composition and method for in situ delivery of broad molecular weight range of chitosan implants with or without therapeutics for regenerative medicine and cartilage repair applications. (Patent Application no. WO2011060554). External link
Hoemann, C. D., & Sun, J. (2011). Two-part cytocompatible system, useful to prepare a cytocompatible polymer composition for repairing e.g. cartilage, comprises a first part liquid solution of a polymer in a first container and a second part liquid solution of a salt. (Patent Application no. WO2011060553). External link
Hoemann, C. D., Chen, G., Marchand, C., Tran-Khanh, N., Thibault, M., Chevrier, A., Sun, J., Shive, M. S., Fernandes, M. J. G., Poubelle, P. E., Centola, M., & El-Gabalawy, H. (2010). Scaffold-Guided Subchondral Bone Repair Implication of Neutrophils and Alternatively Activated Arginase-1+Macrophages. American Journal of Sports Medicine, 38(9), 1845-1856. External link
Hoemann, C. D., Sun, J., McKee, M. D., Chevrier, A., Rossomacha, E., Rivard, G. E., Hurtig, M., & Buschmann, M. D. (2007). Chitosan-Glycerol Phosphate/Blood Implants Elicit Hyaline Cartilage Repair Integrated With Porous Subchondral Bone in Microdrilled Rabbit Defects. Osteoarthritis and Cartilage, 15(1), 78-89. External link
Hoemann, C. D., Chenite, A., Sun, J., Hurtig, M., Serreqi, A., Lu, Z., Rossomacha, E., & Buschmann, M. D. (2007). Cytocompatible Gel Formation of Chitosan-Glycerol Phosphate Solutions Supplemented With Hydroxyl Ethyl Cellulose Is Due to the Presence of Glyoxal. Journal of Biomedical Materials Research. Part A, 83A(2), 521-529. External link
Hoemann, C. D., Hurtig, M., Rossomacha, E., Sun, J., Chevrier, A., Shive, M. S., & Buschmann, M. D. (2005). Chitosan-Glycerol Phosphate/Blood Implants Improve Hyaline Cartilage Repair in Ovine Microfracture Defects. Journal of Bone and Joint Surgery, 87(12), 2671-2686. External link
Hoemann, C. D., Sun, J., Légaré, A., McKee, M. D., & Buschmann, M. D. (2005). Tissue Engineering of Cartilage Using an Injectable and Adhesive Chitosan-Based Cell-Delivery Vehicle. Osteoarthritis and Cartilage, 13(4), 318-329. External link
Hoemann, C. D., Sun, J., Chrzanowski, V., & Buschmann, M. D. (2002). A Multivalent Assay to Detect Glycosaminoglycan, Protein, Collagen, RNA, and DNA Content in Milligram Samples of Cartilage or Hydrogel-Based Repair Cartilage. Analytical Biochemistry, 300(1), 1-10. External link
Lafantaisie-Favreau, C.-H., Guzmán-Morales, J., Sun, J., Chen, G., Harris, A., Smith, T. D., Carli, A., Henderson, J., Stanish, W. D., & Hoemann, C. D. (2013). Subchondral pre-solidified chitosan/blood implants elicit reproducible early osteochondral wound-repair responses including neutrophil and stromal cell chemotaxis, bone resorption and repair, enhanced repair tissue integration and delayed matrix deposition. BMC Musculoskeletal Disorders, 14(1). Available
Marchand, C., Chen, G., Tran-Khanh, N., Sun, J., Chen, H., Buschmann, M. D., & Hoemann, C. D. (2012). Microdrilled Cartilage Defects Treated With Thrombin-Solidified Chitosan/Blood Implant Regenerate a More Hyaline, Stable, and Structurally Integrated Osteochondral Unit Compared to Drilled Controls. Tissue Engineering Part A, 18(5-6), 508-519. External link
Ma, O., Lavertu, M., Sun, J., Nguyen, S., Buschmann, M. D., Winnik, F. M., & Hoemann, C. D. (2008). Precise Derivatization of Structurally Distinct Chitosans With Rhodamine B Isothiocyanate. Carbohydrate polymer, 72(4), 616-624. External link
Sun, J., Serreqi, A., Buschmann, M. D., Chenite, A., & Hoemann, C. D. (2012). Composition for cytocompatible, injectable, self-gelling chitosan solutions for encapsulating and delivering live cells or biologically active factors. (Patent no. CA2493083). External link