BackgroundFracture healing in osteoporosis is delayed. Quality and speed of fracture healing in osteoporotic fractures are crucial with regard to the outcome of patients. The question arises whether established antiosteoporotic drugs can further improve fracture healing.Materials and methodsOsteoporosis manifests predominantly in the metaphyseal bone. Nevertheless, an established metaphyseal fracture model is lacking. A standardized metaphyseal fracture-healing model with stable plate fixation was developed for rat tibiae. The healing process was analyzed by biomechanical, gene expression, and histomorphometric methods in ovariectomized (OVX) and sham-operated rats (SHAM), compared to standardized estrogen (E)- and raloxifene (R)-supplemented diets.ResultsEstrogen and raloxifene improved the biomechanical properties of bone healing compared to OVX (Yield load: , , , ). Estrogen vs OVX was significant based on a denser trabecular network. Raloxifene greatly induced total callus formation (, , ,), whereas estrogen mainly enhanced new endosteal bone formation. There was no correlation between the gene expression (osteocalcin, collagen1α1, IGF-1, tartrate-resistant phosphatase) in the callus and the morphology and quality of callus formation.ConclusionRaloxifene and estrogen improve fracture healing in osteoporotic bone significantly with regard to callus formation, resistance, and elasticity. The biomechanically stable metaphyseal osteotomy model with T-plate fixation presented here has proven to be appropriate to investigate fracture healing in osteoporosis.
Numerous whole-body vibration (WBV) devices of various forces are available on the market, although their influence on the musculoskeletal system is not yet understood. The effect of different WBVs on bone healing and muscle function was evaluated in rats ovariectomized at 3 months of age. 2 months after ovariectomy, bilateral metaphyseal tibia osteotomy and T-plate osteosynthesis were performed. Rats were divided into groups: intact, OVX, and OVX exposed to vertical WBVs of 35, 50, 70, or 90 Hz (experiment 1) or horizontal WBVs of 30, 50, 70, or 90 Hz (experiment 2) 5 days after osteotomy (0.5 mm, 15 min/day for 30 days). The tibia and gastrocnemius and soleus muscles were collected. Vertical vibrations (>35 Hz) improved cortical and callus densities, enlarged callus area and width, suppressed the tartrate-resistant acid phosphatase gene, enhanced citrate synthase activity, accelerated osteotomy bridging (35 and 50 Hz), upregulated the osteocalcin (Oc) gene (70 Hz), and increased relative muscle weight (50 Hz). Horizontal vibrations reduced cortical width (<90 Hz) and callus density (30 Hz), enhanced alkaline phosphatase (Alp) gene expression (50 Hz), decreased the size of oxidative fibers (35 and 70 Hz), and increased capillary density (70, 90 Hz). Biomechanical data; serum Oc, Alp, and creatine kinase activities; body weight; and food intake did not change after WBVs. Vertical WBVs of 35 and 50 Hz produced more favorable results than the higher frequencies. Horizontal WBV showed no positive or negative effects. Further studies are needed to elucidate the effects of WBV on different physiological systems, and precautions must be taken when implementing WBV in the treatment of patients.
SummaryIn this study, short-term, whole-body vertical vibration at 90 Hz improved trabecular bone quality. There was an improvement of bone quality and density in both osteoporotic and control rats. This treatment may therefore be an attractive option for the treatment of osteoporosis.IntroductionAside from pharmacological treatment options, physical exercise is known to augment bone mass. In this study, the effects of whole-body vertical vibration (WBVV) on bone quality and density were evaluated using an osteoporotic rat model.MethodsSixty female Sprague Dawley rats were ovariectomized (C) or sham (SHAM) operated at the age of 3 months. After 3 months, both groups were divided into two subgroups that received either WBVV at 90 Hz for 35 days or no treatment. After sacrificing the rats, we evaluated vertebral bone strength, histomorphometric parameters, and bone mineral density (BMD).ResultsTreatment with WBVV resulted in improved biomechanical properties. The yield load after WBVV was significantly enhanced. According to yield load and Young’s modulus, the treated OVX rats reached the level of the untreated SHAM animals. In all measured histomorphometric parameters, WBVV significantly improved bone density. Treatment with WBVV demonstrated greater effects on the trabecular bone compared to the cortical bone. The ash-BMD index showed significant differences between treated and untreated rats.ConclusionUsing WBVV as a non-pharmacological supportive treatment option for osteoporosis demonstrated an enhancement of bone strength and bone mass. This procedure may be an attractive option for the treatment of osteoporosis.
As the average age of society increases, identifying and preventing osteoporosis becomes more important. According to the results of the Women's Health Initiative study, substitution of estradiol is not recommended in hormone replacement therapy (HRT), although phytoestrogens might be a safe alternative. In this study, the osteoprotective effects of genistein (Gen), resveratrol (Res) and 8-prenylnaringenin (8PN) were evaluated by analysing bone biomechanical strength and bone mineral density. After ovariectomy, 88 female rats received soy-free food (C), and according to their grouping, were fed estradiol (E), GEN, RES or 8PN for 12 weeks. The phytohormones were given in two dosages. To analyse the osteoprotective effects of the tested substances, bone biomechanical properties and bone mineral density (BMD) were evaluated on the upper tibial metaphysis. Bone biomechanical properties were significantly improved after treatment with E (F (max): 90.6 N) and 8PN (85.0 N) compared to GEN (76.0 N), RES (72.6 N) and C (76.6 N). Bone biomechanical properties with 8PN (yL: 55.7 N) supplementation reached a level similar to that seen after E (49.3 N) supplementation. Treatment with GEN (38.5 N) was not as effective as E and 8PN, but demonstrated improved biomechanical properties compared to C (40.1 N) and RES (36.3 N). E (Cn.Dn. 217 mg/cm (3)) and 8PN (165 mg/cm3) showed superior results in the analysis of bone mineral density compared to C (112 mg/cm (3)). GEN (164 mg/cm (3)) also demonstrated superior results, though not as good as E and 8PN. RES (124 mg/cm (3)) revealed no effect on bone density. Treatment with 8PN resulted in very good biomechanical properties and showed an increased BMD. GEN had a smaller effect on bone biomechanical strength, while RES did not have an effect on bone biomechanical strength or BMD. Therefore, 8PN might be a safe alternative for HRT, but further studies are needed.
The antimicrobial activity of cetylpyridinium chloride (CPC) and miramistin (MST) solutions at different concentrations (5¾10 "5 to 0.4 %) and a dressing, containing 0.15 % CPC, were tested against Staphylococcus aureus, Pseudomonas aeruginosa and Escherichia coli after 30 (solutions) and 60 min (fleece) incubation, respectively. Furthermore, the cytotoxic effects of CPC and MST were examined in human keratinocyte (HaCaT) and murine fibroblast (L929) cell lines. A dose of 3¾10 "3 % CPC or MST was sufficient to entirely eradicate S. aureus after 30 min incubation. To achieve the same effect, higher concentrations were required against E. coli (0.025 % CPC; 0.0125 % MST) and P. aeruginosa (0.5 % CPC; 0.05 % MST). The CPC-fleece showed a high antiseptic effect against all three bacterial strains, although it did not completely eliminate P. aeruginosa. Both substances showed a high cytotoxic impact at higher tested concentrations (CPC .3¾10 "3 %; MST .8¾10 "4 %). CPC showed high antimicrobial potency at low concentrations against S. aureus, accompanied by low cytotoxic (side) effects at these concentrations, whilst the required minimal concentration to eradicate E. coli and P. aeruginosa was shown to be cytotoxic for keratinocytes and fibroblasts. The necessary antibacterial amounts of MST were lower, but also cytotoxic in direct contact with typical human wound cells. With regard to demographic changes and increasing bacterial resistance, new effective antiseptics, such as CPC and MST, incorporated in wound dressings without releasing an active substance could help to improve the treatment and healing rates of chronic wounds.
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