Fluid Pressure in Articular Cartilage and Meniscus - Fibril Reinforced Modelling

Abstracts for the public

Technical Papers

  1. Li LP, Soulhat J, Buschmann MD and Shirazi-Adl A (1999). Nonlinear analysis of cartilage in unconfined ramp compression using a fibril reinforced poroelastic model. Clinical Biomechanics 14, 673-682
    | Cited By in Scopus (197)
  2. Li LP, Buschmann MD and Shirazi-Adl A (2000). A fibril reinforced nonhomogeneous poroelastic model for articular cartilage: inhomogeneous response in unconfined compression. Journal of Biomechanics 33, 1533-1541
    | Cited By in Scopus (141)
  3. Li LP, Buschmann MD and Shirazi-Adl A (2001). The asymmetry of transient response in compression vs release for cartilage in unconfined compression. ASME Journal of Biomechanical Engineering 123, 519-522
    | Cited By in Scopus (18)
  4. Li LP, Buschmann MD and Shirazi-Adl A (2002). The role of fibril reinforcement in the mechanical behavior of cartilage. Biorheology 39 (1-2), 89-96
    | Cited By in Scopus (25)
  5. Li LP, Shirazi-Adl A and Buschmann MD (2002). Alterations in mechanical behavior of articular cartilage due to changes in depth varying material properties - a nonhomogeneous poroelastic model study. Computer Methods in Biomechanics and Biomedical Engineering 5, 45-52
    | Cited By in Scopus (20)
  6. Li LP, Shirazi-Adl A and Buschmann MD (2003). Investigation of mechanical behavior of articular cartilage by fibril reinforced poroelastic models. Biorheology 40 (1-3), 227-233
    | Cited By in Scopus (21)
  7. Li LP, Buschmann MD and Shirazi-Adl A (2003). Strain-rate dependent stiffness of articular cartilage in unconfined compression. ASME Journal of Biomechanical Engineering 125, 161-168 | (Erratum: 125, 566)
    | Cited By in Scopus (102)
  8. Li LP and Herzog W (2004). Strain-rate dependence of cartilage stiffness in unconfined compression: the role of fibril reinforcement versus tissue volume change in fluid pressurization. Journal of Biomechanics 37 (3), 375-382
    | Cited By in Scopus (63)
  9. Li LP and Herzog W (2004). The role of viscoelasticity of collagen fibers in articular cartilage: theory and numerical formulation. Biorheology 41 (3-4), 181-194
    | Cited By in Scopus (49)
  10. Li LP, Herzog W, Korhonen RK and Jurvelin JS (2005). The role of viscoelasticity of collagen fibers in articular cartilage: axial tension versus compression Medical Engineering & Physics 27 (1), 51-57 | Ranked 21 in the Top 25 Hottest Articles, 2nd quarter of 2005; Ranked 14 in the Top 25 Hottest Articles, 4th quarter of 2005
    | Cited By in Scopus (83)
  11. Li LP and Herzog W (2005). Electromechanical response of articular cartilage in indentation - Considerations on the determination of cartilage properties during arthroscopy. Computer Methods in Biomechanics and Biomedical Engineering 8 (2), 83-91
    | Cited By in Scopus (10)
  12. Li LP and Herzog W (2006). Arthroscopic evaluation of cartilage degeneration using indentation testing - Influence of indenter geometry. Clinical Biomechanics 21, 420-426
    | Cited By in Scopus (29)
  13. Li LP, Korhonen RK, Iivarinen J, Jurvelin, JS and Herzog W (2008). Fluid pressure driven fibril reinforcement in creep and relaxation tests of articular cartilage. Medical Engineering & Physics 30 (2), 182-189 | Ranked 13 in the Top 25 Hottest Articles, 1st quarter of 2008
    | Cited By in Scopus (43)
  14. Li LP, Cheung JTM and Herzog W (2009). Three-dimensional fibril-reinforced finite element model of articular cartilage. Medical & Biological Engineering & Computing 47(6), 607-615
    | Cited By in Scopus (63)
  15. Gu KB and Li LP (2011). A human knee joint model considering fluid pressure and fiber orientation in cartilages and menisci. Medical Engineering & Physics 33(4), 497-503 | Ranked 22 in the Top 25 Hottest Articles, 1st quarter of 2011; Ranked 23 in the Top 25 Hottest Articles, 2nd quarter of 2011
    | Cited By in Scopus (80)
  16. Kazemi M, Li LP, Savard P and Buschmann MD (2011). Creep behavior of the intact and meniscectomy knee joints. Journal of the Mechanical Behavior of Biomedical Materials 4(7), 1351-1358
    | Cited By in Scopus (54)
  17. Li LP and Gu KB (2011). Reconsideration on the use of elastic models to predict the instantaneous load response of the knee joint. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine 225(9), 888-896
    | Cited By in Scopus (21)
  18. Kazemi M, Li LP, Buschmann MD and Savard P (2012). Partial meniscectomy changes fluid pressurization in articular cartilage in human knees. Journal of Biomechanical Engineering 134(2), 021001, 10 pages
    | Top 10 Most Downloaded Articles, March 2012 | Featured on the cover of the journal
    | Cited By in Scopus (29)
  19. Kazemi M and Li LP (2012). Computational poromechanics of human knee joint. Journal of Physics: Conference Series 341, doi:10.1088/1742-6596/341/1/012014, 6 pages
  20. Kazemi M, Dabiri Y and Li LP (2013). Review article : Recent advances in computational mechanics of the human knee joint (Table of contents). Computational and Mathematical Methods in Medicine (Click here for volumes from 1997-2010) Vol. 2013, Article ID 718423, doi: 10.1155/2013/718423, 27 pages
    | Cited By in Scopus (76)
  21. Dabiri Y and Li LP (2013). Altered knee joint mechanics in simple compression associated with early cartilage degeneration. Computational and Mathematical Methods in Medicine Vol. 2013, Article ID 862903, doi: 10.1155/2013/862903, 11 pages
    | Cited By in Scopus (25)
  22. Atarod M, Rosvold JM, Kazemi M, Li LP, Frank CB and Shrive NG (2013). Inter-insertional distance is a poor correlate for ligament load: Analysis from in vivo gait kinetics data. Journal of Biomechanics 46 (13), 2264-2270
    | Cited By in Scopus (8)
  23. Dabiri Y and Li LP (2013). Influences of the depth-dependent material inhomogeneity of articular cartilage on the fluid pressurization in the human knee. Medical Engineering & Physics 35(11), 1591-1598
    | Cited By in Scopus (21)
  24. Kazemi M and Li LP (2014). A viscoelastic poromechanical model of the knee joint in large compression. Medical Engineering & Physics 36(8), 998-1006
    | Cited By in Scopus (33)
  25. Dabiri Y and Li LP (2015). Focal cartilage defect compromises fluid-pressure dependent load support in the knee joint. International Journal for Numerical Methods in Biomedical Engineering 31(6), DOI: 10.1002/cnm.2713, 12 pages
    | Cited By in Scopus (12)
  26. Ahsanizadeh S and Li LP (2015). Visco-hyperelastic constitutive modeling of soft tissues based on short and long-term internal variables. BioMedical Engineering OnLine 14:29, DOI: 10.1186/s12938-015-0023-7, 16 pages
    | Highly Accessed | Cited By in Scopus (18)
  27. Ahsanizadeh S and Li LP (2015). Strain-rate dependent nonlinear tensile properties of the superficial zone of articular cartilage. Connective Tissue Research 56(6), 469-476 (Online)
    | Cited By in Scopus (11)
  28. Rodriguez ML and Li LP (2017). Compression-rate-dependent nonlinear mechanics of normal and impaired porcine knee joints. BMC Musculoskeletal Disorders 18:447, 10 pages, doi.org/10.1186/s12891-017-1805-9
    | Cited By in Scopus (10)
  29. Uzuner S, Rodriguez ML, Li LP and Kucuk S (2019). Dual fluoroscopic evaluation of human tibiofemoral joint kinematics during a prolonged standing: A pilot study. Engineering Science and Technology, an International Journal 22(3), 794-800
    | Cited By in Scopus (3)
  30. Uzuner S, Li LP, Kucuk S and Memisoglu K (2020). Changes in knee joint mechanics after medial meniscectomy determined with a poromechanical model. Journal of Biomechanical Engineering 142(10): 101006, 9 pages. doi.org/10.1115/1.4047343
    | Cited By in Scopus (1)
  31. Komeili A, Rasoulian A, Moghaddam F, El-Rich M and Li LP (2021).  The importance of intervertebral disc material model on the prediction of mechanical function of the cervical spineBMC Musculoskeletal Disorders 22(1): 324, 12 pages, doi.org/10.1186/s12891-021-04172-1
    | Cited By in Scopus (6)
  32. Otoo BS, Li LP, Hart DA and Herzog W (2022). Development of a porcine model to assess the effect of in situ knee joint loading on site-specific cartilage gene expression. Journal of Biomechanical Engineering 144(2): 024502, 6 pages, doi.org/10.1115/1.4051922 (Supplementary data | Click the link after References section of online version)
  33. Uzuner S, Kuntze G, Li LP, Ronsky JL, and Kucuk S (2022). Creep behavior of human knee joint determined with high-speed biplanar video-radiography and finite element simulation. Journal of the Mechanical Behavior of Biomedical Materials, 125, 104905. doi.org/10.1016/j.jmbbm.2021.104905
  34. Hamsayeh Abbasi Niasar E,  Li LP (2023). Characterizing site-specific mechanical properties of knee cartilage with indentation-relaxation maps and machine learning. Journal of the Mechanical Behavior of Biomedical Materials 142,105826. doi.org/10.1016/j.jmbbm.2023.105826.
  35. Uzuner S, Li LP (2024). Alteration in ACL loading after total and partial medial meniscectomy. BMC Musculoskeletal Disorders 25:94, 11 pages, https://doi.org/10.1186/s12891-024-07201-x
  36. Hamsayeh Abbasi Niasar E, Brenneman Wilson EC, Quenneville CE, Maly MR,  Li LP (2024). Region partitioning of articular cartilage with streaming-potential-based parameters and indentation maps. Journal of the Mechanical Behavior of Biomedical Materials, 106534. https://doi.org/10.1016/j.jmbbm.2024.106534
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