Abstracts accepted to ORS!

The Christiansen Lab has 3 posters and 1 podium presentation for ORS 2017 in San Diego, CA!

Podium Presentation

Stephanie Telek: Loss of Bone Stiffness at a Distant Skeletal Site Following Femoral Fracture in Mice


Armaun Emami: Age-Dependent Systemic Bone Loss and Recovery Following Femoral Fracture in Mice

Allison Hsia: Osteophyte Formation and the Effect of Mechanical Loading: Comparisons to Fracture Healing in Mice

Franklin Tarke: Comparison of Knee Injury Threshold During Tibial Compression Based on Limb Orientation in Mice


Congratulations Stephanie, Armaun, Allison, and Franklin!


Collette et al. 2016 featured on News-Medical.net

Our work with the Loots Lab at Lawrence Livermore National Labs has been featured on News-Medical.net! The study is titled, “Sostdc1 deficiency accelerates fracture healing by promoting the expansion of periosteal mesenchymal stem cells,” and will be published in Bone in July 2016.

Read the News-Medical.net report here: http://www.news-medical.net/news/20160602/Sostdc1-gene-may-play-vital-role-in-fracture-healing-process.aspx

Osteophyte development restabilizes the knee at the cost of range of motion

Our recent study, Osteophyte Formation After ACL Rupture in Mice is Associated With Joint Restabilization and Loss of Range of Motion, published in the Journal of Orthopaedic Research examined osteophyte development throughout the full time course of osteoarthritis (OA) and its effect on joint function. We used our noninvasive ACL rupture mouse model of post-traumatic OA (PTOA) to investigate how osteophyte formation correlated with changes in joint stability, characterized by anterior-posterior joint laxity, and range of motion (ROM). Stability and ROM both increased immediately after ACL rupture, but began decreasing only 2 weeks post-injury. Stability was restored to control levels after 8 weeks of injury, but ROM in injured limbs was significantly less than that of uninjured knees. These changes in joint function correlated well with osteophyte growth, but only if early chondrophyte development was also taken into consideration. This study suggests that while osteophytes do play a role in joint stabilization during PTOA, chondrophyte formation must be taken into consideration. Few studies currently examine chondrophyte formation, and these findings emphasize the importance of increasing our understanding of chondrophytes in osteophyte formation and OA progression.

Be sure to check out our study in the Journal of Orthopaedic Research!

Hsia et al. J Orthop Res (2016). DOI: 10.1002/jor.23252.

Alendronate prevents early joint degeneration following ACL injury

Our recent paper, Effect of alendronate on post-traumatic osteoarthritis induced by anterior cruciate ligament rupture in mice, published in Arthritis Research & Therapy, investigates the effect of a current osteoporosis treatment, alendronate, on joint health following injury. Alendronate is already understood to prevent bone loss, but has also been considered a contender for the treatment of osteoarthritis due to its potentially protective effects on cartilage. We used our novel, non-invasive mouse model of knee osteoarthritis to evaluate how two different alendronate regimens (low- and high-dose) influenced joint health after ACL rupture. We found that a high-dose of alendronate was able to prevent early bone loss and cartilage degeneration following injury, but that long-term joint degenerative effects were unmitigated. These results contribute to the knowledge surrounding alendronate and joint health, and may support the use of alendronate and other similar drugs following joint injury.

For more details, check out our paper in Arthritis Research & Therapy!

Khorasani et al. Arthritis Research & Therapy (2015) 17:30. DOI: 10.1186/s13075-015-0546-0