Comparison of strain generated in bone by "platform-switched" and "non-platform-switched" implants with straight and angulated abutments under vertical and angulated load: A finite element analysis study.

Purpose: The aim of this study was to evaluate the microstrain exhibited by bone around immediately loaded, platform-switched, and non-platform-switched implants under vertical and angled loading using a finite element analysis (FEA) and also to evaluate whether platform-switched implants evoke a better response than non-platform-switched implants on a mechanical basis. Materials and Methods: Three-dimensional finite element study was undertaken to model and analyze an immediate loaded situation. FEA was chosen for this study since it is useful in determining the stress and strain around the dental implant. Bone responses to vertical and angulated loads on straight and angulated abutments (platform-switched and non-platform-switched abutments) were evaluated. Results: Non-platform-switched abutments tend to exhibit a lower tensile stress and compressive stress but higher microstrain value (conducive to higher chance of bone resorption) than platform-switched abutments. Ideal bone remodeling values of microstrain (50-3000 μϵ) were exhibited by platform-switched straight abutments under vertical load and angled load (with an abutment-implant diameter difference of 1 mm). Conclusion: In spite of the obvious advantages, the practice of immediate loading is limited due to apprehension associated with compromised bone response and a higher rate of bone loss around an immediately loaded implant. The mechanical basis for the concept of "platform switching" in immediately loaded situation is analyzed in this context. The results of this limited investigation indicated that the ideal values of microstrain (50-3000 microstrain) can be exhibited by platform switching of dental implants (with an abutment-implant diameter difference of 1 mm) and can be considered as a better alternative for prevention of crestal bone loss when compared to non-platform-switched implants.

Bone Response to Hormone Therapy according to Basal Bone Mineral Density and Previous Response to Hormone Therapy / 대한폐경학회지

OBJECTIVES: To investigate bone responses to hormone therapy (HT) according to basal bone mineral density (BMD) and previous responses to HT, as well as the frequency and clinical characteristics of HT non-responders in Korean postmenopausal women. METHODS: We retrospectively reviewed a total of 1,836 postmenopausal women who received HT from seven university hospitals. BMD data at the lumbar spine (LS), femur neck (FN), femur trochanter (FT) and total hip (TH) before HT, and at one, two, and three years after HT were collected. All patients were divided into three groups according to basal BMD: normal, osteopenia, and osteoporosis. RESULTS: Women with a greater loss of BMD during the first year of HT were more likely to gain BMD in the second year at any of the four skeletal sites. Bone responses to HT during the third year were not related to the responses during the first year. Mean BMD changes during the first year were significantly higher in the osteoporosis group, but mean BMD changes during the second year were not different between three groups except in LS. The frequency of non-responder (annual BMD losses more than 3%) during the first year was significantly higher in the normal basal BMD group. Mean basal BMDs were higher in the two-year consecutive non-responder group at LS, FN and FT, but those of the three-year consecutive non-responder group were not significantly higher except in FN. CONCLUSION: Most women who lose BMD after HT are likely to gain BMD during the next year. The frequency of non-responders is higher in the higher basal BMD group, and patients with lower basal BMD will be likely to respond better to HT.

Bone response to biosilicates® with different crystal phases

The aim of this study was to investigate the histological and histomorphometrical bone response to three Biosilicates with different crystal phases comparing them to Bioglass®45S5 implants used as control. Ceramic glass Biosilicate and Bioglass®45S5 implants were bilaterally inserted in rabbit femurs and harvested after 8 and 12 weeks. Histological examination did not revealed persistent inflammation or foreign body reaction at implantation sites. Bone and a layer of soft tissue were observed in close contact with the implant surfaces in the medullary canal. The connective tissue presented few elongated cells and collagen fibers located parallel to implant surface. Cortical portion after 8 weeks was the only area that demonstrated significant difference between all tested materials, with Biosilicate 1F and Biosilicate 2F presenting higher bone formation than Bioglass®45S5 and Biosilicate® vitreo (p=0.02). All other areas and periods were statistically non-significant (p>0.05). In conclusion, all tested materials were considered biocompatible, demonstrating surface bone formation and a satisfactory behavior at biological environment.

O objetivo deste estudo foi investigar histologicamente e histomorfometricamente a resposta óssea a três diferentes fases cristalinas do Biosilicato®, comparando-os aos implantes de Bioglass®45S5 utilizados como controles. Implantes de cerâmicas de Biosilicato® e implantes de Bioglass®45S5 foram inseridos bilateralmente em fêmures de coelho e avaliações histológicas realizadas após 8 e 12 semanas. As avaliações histológicas não revelaram inflamação persistente ou reação de corpo estranho nos sítios de implantação dos biovidros. A formação de tecido ósseo pôde ser observada em maior quantidade na porção cortical, com tecido conjuntivo sendo observado em íntimo contato com as superfícies dos implantes apenas na porção medular. O tecido conjuntivo apresentou células com forma alongada e fibras de colágeno localizado paralelamente à superfície do implante. A porção cortical (após 8 semanas) foi a única área que demonstrou diferença significante entre os materiais estudados, com o Biosilicato 1F e o Biosilicato 2F demonstrando maior formação de tecido ósseo em contato com a superfície quando compardos aos implantes de Bioglass®45S5 e Biosilicato®vítreo (p=0,02). As outras áreas estudadas nos diferentes períodos não foram consideradas estatisticamente significantes (p>0,05). Pode-se concluir que todos os materiais testados foram considerados biocompatíveis, com formação óssea na superfície e comportamento em ambiente biológico satisfatório.

The Biological Effects of Calcium Phosphate Coated Implant for Osseointegration in Beagle Dogs / 대한치주과학회지

The influence of calcium phosphate (Ca-P) coating on the bone response of titanium implants was investigated two types of titanium implants, i.e. as -machined ,as -machined with Ca-P coating, were prepared. The Ca-P coating produced by OCT Inc technique. These implants were inserted into the left and right femur of beagle dog. After implantation periods of 3 days, 1weeks, weeks, 4weeks, 8weeks, 12weeks, 24weeks, the bone-implant interface was evaluated histologically, histomorphometrically, and removal torque. Histological evaluation revealed no new bone formation around different implant materials after 2weeks of implantation. After 4 weeks, Ca-P coated implants showed a higher amount of bone contact than either of the non coated implants. After 12weeks, bone healing was almost completed. And implant were removed by reverse torque rotation with torque-measuring device. Mean torque values for 4weeks control were 2.375Kgf.cm and experimental were 2.725Kgf.cm. And mean torque values for 8weeks control were 1.25Kgf.cm and experimental were 1.0Kgf.cm On the basis of these findings, we concluded that deposition of a Ca-P coating on an implant has a beneficial effect on the bone response to this implant during the healing phase. Besides implant surface conditions the bone response is also determined by local implant site condition.