Connexin 43 deficiency desensitizes bone to the effects of mechanical unloading through modulation of both arms of bone remodeling

Authors

Shane A. Lloyd, Alayna E. Loiselle, Yue Zhang, Henry J. Donahue

Abstract

Connexin 43 (Cx43) is a gap junction protein that plays an integral role in the skeletal response to mechanical loading and unloading. In a previous study, we demonstrated preservation of trabecular bone mass and cortical bone formation rate in mice with an osteoblast/osteocyte-selective deficiency of Cx43 (cKO) following mechanical unloading via hindlimb suspension (HLS). In the present study, we sought to define the potential mechanisms underlying this response. Following three weeks of HLS, mRNA levels of Sost were significantly greater in wild-type (WT)-Suspended mice vs. WT-Control, while there was no difference between cKO control and cKO-Suspended. Unloading-induced decreases in P1NP, a serum marker of bone formation, were also attenuated in cKO-Suspended. The proportion of sclerostin-positive osteocytes was significantly lower in cKO-Control vs. WT-Control (− 72%, p < 0.05), a difference accounted for by the presence of numerous empty lacunae in the cortical bone of cKO vs. WT. Abundant TUNEL staining was present throughout the cortical bone of the tibia and femur, suggesting an apoptotic process. There was no difference in empty lacunae in the trabecular bone of the tibia or femur. Trabecular and cortical osteoclast indices were lower in cKO-Suspended vs. WT-Suspended; however, mRNA levels of the gene encoding RANKL increased similarly in both genotypes. Connexin 43 deficient mice experience attenuated sclerostin-mediated suppression of cortical bone formation and lower cortical osteoclast activity during unloading. Preservation of trabecular bone mass and attenuated osteoclast activity during unloading, despite an apparent lack of effect on osteocyte viability at this site, suggests that an additional mechanism independent of osteocyte apoptosis may also be important. These findings indicate that Cx43 is able to modulate both arms of bone remodeling during unloading.

Link to Article

http://dx.doi.org/10.1016/j.bone.2013.07.022

Neonatal iron deficiency causes abnormal phosphate metabolism by elevating FGF23 in normal and ADHR mice

Authors

Erica L. Clinkenbeard PhD, Emily G. Farrow PhD, Lelia J. Summers, Taryn A. Cass, Jessica L. Roberts, Christine A. Bayt, Tim Lahm MD, Marjorie Albrecht, Matthew R. Allen PhD, Munro Peacock MD, Kenneth E. White PhD

Abstract

FGF23 gain of function mutations can lead to autosomal dominant hypophosphatemic rickets (ADHR) disease onset at birth, or delayed onset following puberty or pregnancy. We previously demonstrated that the combination of iron deficiency and a knock-in R176Q FGF23 mutation in mature mice induced FGF23 expression and hypophosphatemia that paralleled the late onset ADHR phenotype. As anemia in pregnancy and in premature infants is common, the goal of this study was to test whether iron deficiency alters phosphate handling in neonatal life. Wild type (WT) and ADHR female breeder mice were provided control or iron-deficient diets during pregnancy and nursing. Iron-deficient breeders were also made iron replete. Iron deficient WT and ADHR pups were hypophosphatemic, with ADHR pups having significantly lower serum phosphate (P < 0.01) and widened growth plates. Both genotypes increased bone FGF23 mRNA (>50 fold; P < 0.01). WT and ADHR pups receiving low iron had elevated intact serum FGF23 with ADHR mice affected to a greater degree (P < 0.01). Iron deficient mice also showed increased Cyp24a1 and reduced Cyp27b1, and low serum 1,25(OH)2 vitamin D. Iron repletion normalized most abnormalities. Because iron deficiency can induce tissue hypoxia, oxygen deprivation was tested as a regulator of FGF23, and was shown to stimulate FGF23 mRNA in vitro and serum C-terminal FGF23 in normal rats in vivo. These studies demonstrate that FGF23 is modulated by iron status in young WT and ADHR mice and that hypoxia independently controls FGF23 expression in situations of normal iron. Therefore, disturbed iron and oxygen metabolism in neonatal life may have important effects on skeletal function and structure through FGF23 activity on phosphate regulation.

Link to Article

http://dx.doi.org/10.1002/jbmr.2049

Distraction Osteogenesis Following Low-Dose Hyperfractionated Irradiation in the Rat Mandible

Authors

Sagar S. Deshpande, BS, Laura A. Monson, MD, Christi M. Cavaliere, MD, Alexander L. Ayzengart, MD, Steven R. Buchman, MD

Abstract

Purpose: The investigators hypothesized that low-dose hyperfractionated radiation would impair mandibular distraction osteogenesis (DO) in a murine mandibular model. Materials and Methods: Male Sprague-Dawley rats underwent fractionated radiation (30 Gy) of the left mandible. After a 2-week recovery period, an external frame distractor was applied and gradual distraction of the mandible was performed. Tissue was harvested after a 28-day consolidation period. Gross, radiologic, and histologic evaluations were undertaken. Control animals underwent surgery for an identical time frame without preoperative radiation. Results: Animals subjected to preoperative radiation (n = 10) showed suboptimal bone formation, including bone atrophy, incomplete bridging of the distraction gap, and gross bony defects or nonunion, compared with controls (n = 10). Although physical lengthening was achieved, irradiation consistently led to a detrimental effect on the normal process of DO. Conclusion: This set of experiments establishes a valuable rodent model to evaluate the effects of radiation on DO and may help to formulate strategies to optimize DO before it is widely applied in oncologic reconstruction.

Link to Article

http://dx.doi.org/10.1016/j.joms.2013.02.011

Treatment with resveratrol attenuates sublesional bone loss in spinal-cord-injured rats

Authors

Hua-Dong Wang, Ya-Min Shi, Li Li, Ji-Dong Guo, Yu-Peng Zhang, Shu-Xun Hou

Abstract

Background and purpose: Sublesional osteoporosis predisposes individuals with spinal cord injury (SCI) to an increased risk of low-trauma fracture. The aim of present work was to investigate the effect of treatment with resveratrol (RES) on sublesional bone loss in spinal-cord-injured rats. Experimental approach: Complete SCI was generated by surgical transaction of the cord at the T10-12 level. Treatment with RES (400 mg/kg body mass/day, intragastrically) was initiated 12 hours after the surgery for 10 days. Then, blood was collected and femurs and tibiae were removed for evaluation of the effects of RES on bone tissue after SCI. Key results: Treatment of SCI rats with RES prevented the reduction of bone mass including bone mineral content and bone mineral density in tibiae, preserved bone structure including trabecular bone volume fraction, trabecular number, and trabecular thickness in tibiae, and preserved mechanical strength including ultimate load, stiffness, and energy in femurs. Treatment of SCI rats with RES enhanced femoral t-SH content, reduced femoral malondialdehyde and IL-6 mRNA levels. Treatment of SCI rats with RES suppressed the upregulation of mRNA levels of PPARγ, aP2, and LPL, and restored mRNA levels of Wnt1, Lrp5, Axin2, ctnnb1, IGF-1 and IGF-1R in femurs and tibiae. Conclusions and Implications: Treatment with RES attenuated sublesional bone loss in spinal-cord-injured rats, associated with abating oxidative stress, attenuating inflammation, depressing PPARγ signaling, and restoring Wnt/β-catenin and IGF-1 signaling.

Link to Article

http://dx.doi.org/10.1111/bph.12301

The Effects of Loading on the Preload and Dimensions of the Abutment Screw for a 3-Unit Cantilever-Fixed Prosthesis Design

Authors

Setia, Gaurav DDS, Yousef, Hoda DMD, MS, Ehrenberg, David DDS, MS, Luke, Allyn BA, BSCE, MSCE, Weiner, Saul DDS

Abstract

Objective: The purpose of this study was to use an in vitro model system to compare the effects on the screw torque and screw dimensions within 2 commercially available implant systems from occlusal loading on a cantilevered-fixed partial denture. Materials and Methods: Cantilevered implant-supported 3-unit prostheses with 2 premolar abutments and 1 premolar pontic (7.3 mm in length) were made on resin casts containing 2 implant analogs for 2 implant systems: BioLok Silhouette Tapered Implant System (Birmingham, AL) and Zimmer Tapered Screw-Vent Implant System (Carlsbad, CA) with 10 samples in each group. Each sample was loaded with either of 2 protocols: (1) a load of 50 N on the cantilevered pontic unit and (2) a loading of 150 N on all 3 units. The outcome measures were (1) changes in residual torque of the abutment screws and (2) changes in screw dimension. Results: The BioLok Silhouette Tapered Implant group demonstrated slight but statistically significant torque loss 18.8% to 28.5% in both abutment screws for both protocols, P <= 0.05, without any changes in screw dimension. In the Zimmer Tapered Screw-Vent Implant group, there was a significant elongation of the abutment screws and a markedly significant 44.4%, (P <= 0.01) loss in torque in the mesial screw and a 28.5%, (P <= 0.05) loss in torque in the distal screw when the cantilever alone was loaded. Conclusions: Differences in screw design influence the maintenance of preload and distortion of the shank. The influence of the interface design, namely an internal hex of 1 mm versus an external hex did not influence the preload. Cantilevered prostheses can cause loss of torque and dimensional changes in abutment screws.

Link to Article

http://dx.doi.org/10.1097/ID.0b013e31829c227a

Matrix generation within a macroporous non-degradable implant for osteochondral defects is not enhanced with partial...

Title

Matrix generation within a macroporous non-degradable implant for osteochondral defects is not enhanced with partial enzymatic digestion of the surrounding tissue: evaluation in an in vivo rabbit model

Authors

Aaron J. Krych, Florian Wanivenhaus, Kenneth W. Ng, Stephen Doty, Russell F. Warren, Suzanne A. Maher

Abstract

Articular cartilage defects are a significant source of pain, have limited ability to heal, and can lead to the development of osteoarthritis. However, a surgical solution is not available. To tackle this clinical problem, non-degradable implants capable of carrying mechanical load immediately after implantation and for the duration of implantation, while integrating with the host tissue, may be viable option. But integration between articular cartilage and non-degradable implants is not well studied. Our objective was to assess the in vivo performance of a novel macroporous, nondegradable, polyvinyl alcohol construct. We hypothesized that matrix generation within the implant would be enhanced with partial digestion of the edges of articular cartilage. Our hypothesis was tested by randomizing an osteochondral defect created in the trochlea of 14 New Zealand white rabbits to treatment with: (i) collagenase or (ii) saline, prior to insertion of the implant. At 1 and 3-month post-operatively, the gross morphology and histologic appearance of the implants and the surrounding tissue were assessed. At 3 months, the mechanical properties of the implant were also quantified. Overall, the hydrogel implants performed favorably; at all time-points and in all groups the implants remained well fixed, did not cause inflammation or synovitis, and did not cause extensive damage to the opposing articular cartilage. Regardless of treatment with saline or collagenase, at 1 month post-operatively implants from both groups had a contiguous interface with adjacent cartilage and were populated with chondrocyte-like cells. At 3 months fibrous encapsulation of all implants was evident, there was no difference between area of aggrecan staining in the collagenase versus saline groups, and implant modulus was similar in both groups; leading us to reject our hypothesis. In summary, a porous PVA osteochondral implant remained well fixed in a short term in vivo osteochondral defect model; however, matrix generation within the implant was not enhanced with partial digestion of adjacent articular cartilage.

Link to Article

http://dx.doi.org/10.1007/s10856-013-4999-x