Meniscus allograft transplantation has become a viable treatment option for selected symptomatic patients who have undergone a complete or near-complete meniscectomy. Preliminary basic and clinical studies have suggested that meniscus allograft transplantation may help alleviate pain and improve knee function. However, the efficacy of transplantation to restore normal meniscus function compromised by meniscectomy has not been rigorously evaluated. There has been a scarcity of converging evidence from both clinical and basic science studies. Critically lacking are quantitative in vivo data and mechanistic descriptions of how meniscus allograft transplantation affects the knee joint function and mechanics. Such data and knowledge bases not only provide direct, most relevant scientific evidence for optimizing the clinical care, but also are much needed for guiding the development of tissue-engineered meniscus constructs. The proposed research is the first attempt to develop such a knowledge base by studying the effects of meniscus allograft transplantation on tibiofemoral kinematics and contact congruency in vivo and in silico. Our long-term goal is to establish a biomechanical science base and a computerized clinical utility for designing individual-optimized meniscus allograft transplantation.
Our specific aims are (1) to characterize the in vivo changes in tibiofemoral kinematics and contact congruency in patients before and after treatment with meniscal transplant surgery during daily activities (level walking, squatting), and (2) to develop and validate a computational in silico model that describes mechanistically the effects of meniscus transplantation of varied characteristics on joint kinematics and contact congruency. We will measure 10 patients'tibiofemoral kinematics using a dynamic biplane radiography system, muscle activations using a wireless EMG system, and whole-body kinematics- kinetics using an optical motion capture system along with an instrumented treadmill. We will obtain high- resolution computed tomography (CT) and magnetic resonance imaging (MRI) scans of the patients. With the data, we will develop patient-specific models using an approach combining forward dynamic simulation and finite element modeling. We will validate the model based on both within-patient and cross-patient predictions. Successful fulfillment of these research aims will build a new biomechanical science foundation and a validated modeling framework for our future pursuit of individual-optimized meniscus transplantation that not only restores joint congruency but also promotes long-term joint health.

Public Health Relevance

Meniscectomy is the most common orthopaedic surgical procedure performed in the United States and has deleterious consequences such as osteoarthritis and muscle dysfunction. Although meniscus transplant surgery has become a viable treatment option to restore normal meniscus function compromised by meniscectomy, its efficacy has not been rigorously evaluated. This grant application seeks to study the effects of meniscus allograft transplantation on tibiofemoral kinematics and contact mechanics using computer models developed from in vivo data.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Small Research Grants (R03)
Project #
5R03AR059939-02
Application #
8128461
Study Section
Special Emphasis Panel (ZAR1-MLB-G (M1))
Program Officer
Panagis, James S
Project Start
2010-08-15
Project End
2013-07-31
Budget Start
2011-08-01
Budget End
2012-07-31
Support Year
2
Fiscal Year
2011
Total Cost
$72,720
Indirect Cost
Name
University of Pittsburgh
Department
Orthopedics
Type
Schools of Medicine
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213
Zheng, Liying; Carey, Robert; Thorhauer, Eric et al. (2018) In vivo tibiofemoral skeletal kinematics and cartilage contact arthrokinematics during decline walking after isolated meniscectomy. Med Eng Phys 51:41-48
Carey, Robert E; Zheng, Liying; Aiyangar, Ameet K et al. (2014) Subject-specific finite element modeling of the tibiofemoral joint based on CT, magnetic resonance imaging and dynamic stereo-radiography data in vivo. J Biomech Eng 136:
Zheng, Liying; Li, Kang; Shetye, Snehal et al. (2014) Integrating dynamic stereo-radiography and surface-based motion data for subject-specific musculoskeletal dynamic modeling. J Biomech 47:3217-21
Zheng, Liying; Harner, Christopher D; Zhang, Xudong (2014) The morphometry of soft tissue insertions on the tibial plateau: data acquisition and statistical shape analysis. PLoS One 9:e96515
Li, Kang; Zheng, Liying; Tashman, Scott et al. (2012) The inaccuracy of surface-measured model-derived tibiofemoral kinematics. J Biomech 45:2719-23
Li, Kang; Langdale, Evan; Tashman, Scott et al. (2012) Gender and condylar differences in distal femur morphometry clarified by automated computer analyses. J Orthop Res 30:686-92