ABSTRACT
La osteonecrosis de maxilar asociada a aminobisfosfonatos (BRONJ) constituye un efecto secundario del tratamiento crónico con los más potentes. Un modelo experimental permitiría determinar la patogenia de dicha alteración. La oveja presenta características orales y del metabolismo óseo similar al humano y permite realizar manipulaciones bucales. Se evaluaron cambios clínicos, remodelación ósea y masa ósea maxilar en ovejas hembras adultas tratadas con zolendronato (ZOL), durante 22 meses y utilizando dosis equivalente al tratamiento de neoplasias. Seis ovariectomizadas (OVX) recibieron ZOL; 5 OVX y 4 SHAM (control) recibieron solución fisiológica. Al inicio, 4 y 22 meses se evaluó calcemia, fosfatemia, crosslaps (CTX) y fosfatasa alcalina ósea. Al final, se evaluó contenido mineral óseo de la hemimandíbula superior (CMO: mg/cm2). Al final del estudio, CTX disminuyó significativamente en ZOL (p<0,05) sin diferencias entre SHAM y OVX. En maxilar, los contenidos de Ca y P (g/g tejido) y CMO (g/cm2 ) disminuyeron en OVX vs. SHAM (p<0,05) y solo Ca y CMO respecto de ZOL (p<0,05). ZOL incrementó el contenido de Ca y CMO, mientras que el de P permaneció significativamente disminuido respecto de SHAM. La sobrevida en SHAM y OVX fue del 100% y en ZOL 77% (2 muertes); 2 ovejas del grupo ZOL presentaron necrosis de maxilar. Conclusiones: fue posible obtener desarrollo de BRONJ por tratamiento crónico con ZOL, el cual redujo notablemente la resorción y, según la relación Ca/P, posiblemente haya afectado la mineralización ósea. (AU)
Bisphosphonate-related osteonecrosis of the jaw (BRONJ) is a complication of chronic treatment with the most powerful aminobisphosphonates (BPs). An experimental animal model would allow to determine the pathogenesis of this complication. Ewes exhibit similar oral cavity characteristics and bone metabolism as humans, and they are suitable for oral cavity interventions. We examined herein the clinical manifestations, bone remodeling status, and maxillary bone mass in adult female ewes treated with zoledronate (ZOL) for 22 months. Six ovariectomized (OVX) ewes received ZOL; and 5 OVX and 4 SHAM animals received saline solution. At the start of the experiment, and at the 4 and 22 month-time points serum Ca, P, crosslaps (CTX), and bone alkaline phosphatase were measured. Bone mineral content (BMC) of the superior hemimandible was measured at the end of the experiment. At this time point, CTX was significantly decreased only in the ZOL group (p<0.05). Ca and P content (g/g tissue) and BMC in the mandible were significantly decreased in the OVX group compared to SHAM animals (p<0.05) and only Ca content and BMC were decreased when compared to ZOL (p<0.05). ZOL treatment increased the Ca content and BMC, whereas the P content remained low compared to the SHAM group (p<0.05). All ewes from the SHAM and OVX groups and 77% of the animals from the ZOL group survived until the end of the experiment, whereas two ewes of ZOL group exhibited BRONJ. Conclusion: under our experimental conditions, it was possible to induce BRONJ by the chronic ZOL administration, which in turn induced a high reduction in bone resorption as well as possibly impaired bone mineralization, based on the Ca/P ratio in the mandible. (AU)
Subject(s)
Animals , Diphosphonates/adverse effects , Bisphosphonate-Associated Osteonecrosis of the Jaw/pathology , Zoledronic Acid/adverse effects , Tooth Extraction , Bone Diseases, Metabolic/chemically induced , Sheep/metabolism , Sheep/blood , Biomarkers/blood , Bone Density/drug effects , Bone Remodeling/drug effects , Densitometry , Experimental Development , Bisphosphonate-Associated Osteonecrosis of the Jaw/etiology , Bisphosphonate-Associated Osteonecrosis of the Jaw/immunology , Bisphosphonate-Associated Osteonecrosis of the Jaw/prevention & control , Zoledronic Acid/administration & dosage , Glucocorticoids/therapeutic use , Analgesics/therapeutic use , Ilium/cytology , Anesthetics, Dissociative/therapeutic use , Lidocaine/therapeutic use , Maxilla/cytology , Maxilla/drug effects , Maxilla/metabolism , Maxilla/diagnostic imaging , Anti-Bacterial Agents/therapeutic useABSTRACT
The functional demand imposed on bone promotes changes in the spatial properties of osteocytes as well as in their extensions uniformly distributed throughout the mineralized surface. Once spatial deformation is established, osteocytes create the need for structural adaptations that result in bone formation and resorption that happen to meet the functional demands. The endosteum and the periosteum are the effectors responsible for stimulating adaptive osteocytes in the inner and outer surfaces.Changes in shape, volume and position of the jaws as a result of skeletal correction of the maxilla and mandible require anchorage to allow bone remodeling to redefine morphology, esthetics and function as a result of spatial deformation conducted by orthodontic appliances. Examining the degree of changes in shape, volume and structural relationship of areas where mini-implants and miniplates are placed allows us to classify mini-implants as devices of subabsolute anchorage and miniplates as devices of absolute anchorage.
Uma demanda funcional sobre o osso promove alterações na forma espacial da rede de osteócitos e seus prolongamentos, distribuídos uniformemente na estrutura mineralizada. A partir da deformação espacial captada, os osteócitos comandam a necessidade de adaptações estruturais, formando osso em novas áreas e reabsorvendo em outras, para que sejam atendidas as demandas funcionais. O endósteo e o periósteo são os verdadeiros efetores desses estímulos osteocíticos adaptativos, nas superfícies internas e externas. As alterações de forma, volume e posição dos ossos maxilares, nas correções esqueléticas da maxila e mandíbula, requerem uma ancoragem para que a remodelação óssea redefina a morfologia, a estética e as funções, a partir de deformações espaciais dirigidas por aparelhos. Verificar o grau de alterações na forma, volume e relações estruturais das áreas onde se fixaram os mini-implantes e as miniplacas poderá levar à classificação dos mini-implantes como dispositivos de ancoragem subabsoluta e as miniplacas, como de ancoragem absoluta.
Subject(s)
Humans , Bone Plates , Dental Implants , Orthodontic Anchorage Procedures/instrumentation , Bone Matrix/physiology , Bone Remodeling/physiology , Bone Resorption/physiopathology , Miniaturization , Mandible/cytology , Maxilla/cytology , Mechanotransduction, Cellular/physiology , Orthodontic Appliance Design , Osteoblasts/physiology , Osteoclasts/physiology , Osteocytes/physiology , Osteogenesis/physiology , Periosteum/physiology , Tooth Movement Techniques/instrumentationABSTRACT
BACKGROUND: Acetylcholine (ACh) is known to be a key neurotransmitter in the central and peripheral nervous systems, which is also produced in a variety of non-neuronal tissues and cell. The existence of ACh in maxilla in vivo and potential regulation role for osteogenesis need further study. RESULTS: Components of the cholinergic system (ACh, esterase, choline acetyltransferase, high-affinity choline uptake, n- and mAChRs) were determined in maxilla of rat in vivo, by means of Real-Time PCR and immunohistochemistry. Results showed RNA for CarAT, carnitine/acylcarnitine translocase member 20 (Slc25a20), VAChT, OCTN2, OCT1, OCT3, organic cation transporter member 4 (Slc22a4), AChE, BChE, nAChR subunits α1, α2, α3, α5, α7, α10, ß1, ß2, ß4, γ and mAChR subunits M1, M2, M3, M4, M5 were detected in rat's maxilla. RNA of VAChT, AChE, nAChR subunits α2, ß1, ß4 and mAChR subunits M4 had abundant expression (2(-ΔCt) > 0.03). Immunohistochemical staining was conducted for ACh, VAChT, nAChRα7 and AChE. ACh was expressed in mesenchymal cells, chondroblast, bone and cartilage matrix and bone marrow cells, The VAChT expression was very extensively while ACh receptor α7 was strongly expressed in newly formed bone matrix of endochondral and bone marrow ossification, AchE was found only in mesenchymal stem cells, cartilage and bone marrow cells. CONCLUSIONS: ACh might exert its effect on the endochondral and bone marrow ossification, and bone matrix mineralization in maxilla.