Comparing the Efficacy of a Microperforated Titanium Membrane for Guided Bone Regeneration with an Existing Mesh Retainer in Dog Mandibles

Acute-type lateral ridge defects (25 mm × 6 mm × 5 mm) were bilaterally created in the mandibles of four dogs (two defects per animal). The defects were reconstructed with particulate autologous bone and covered with a microperforated titanium membrane (Ti-honeycomb membrane, TiHM) or an existing conventional titanium mesh as control. The samples were dissected after 16 weeks postoperatively and processed for radiographic, histologic, and histomorphometric analyses. Regenerated tissue and bone volume were significantly larger in the TiHM group than in the control group (p = 0.05; p = 0.049). In contrast, bone mineral density was similar between the two groups. Histomorphometric analysis revealed that the regenerated bone area and calcific osseous area were larger in the TiHM group than in the control group; however, the differences were not significant. The efficacy of TiHM was generally satisfactory with the potential to become a standard tool for the GBR procedure; however, early membrane exposure will be a major problem to overcome.

Evaluation of Preosteoblast MC3T3-E1 Cells Cultured on a Microporous Titanium Membrane Fabricated Using a Precise Mechanical Punching Process

The surface topography of Titanium (Ti) combined toughness and biocompatibility affects the attachment and migration of cells. Limited information of morphological characteristics, formed by precise machining in micron order, is currently available on the Ti that could promote osteoconduction. In the present study, a pure Ti membrane was pierced with precise 25 μm square holes at 75 μm intervals and appear burrs at the edge of aperture. We defined the surface without burrs as the “Head side” and that with burrs as the “Tail side”. The effects of the machining microtopography on the proliferation and differentiation of the preosteoblasts (MC3T3-E1 cells) were investigated. The cells were more likely to migrate to, and accumulate in, the aperture of holes on the head side, but grew uniformly regardless of holes on the tail side. The topography on the both surfaces increased osteopontin gene expression levels. Osteocalcin expression levels were higher on the head side than one on the blank scaffold and tail side (p < 0.05). The osteocalcin protein expression levels were higher on the tail side than on the head side after 21 days of cultivation, and were comparable to the proportion of the calcified area (p < 0.05). These results demonstrate the capacity of a novel microporous Ti membrane fabricated using a precise mechanical punching process to promote cell proliferation and activity.

Vertical ridge augmentation with a honeycomb structure titanium membrane: A technical note for three-dimensional curvature bending method

Guided bone regeneration (GBR) is the most commonly used technique for vertical ridge augmentation (VRA), and is popular because it is less invasive and highly formative. Since the augmented site is exposed to external pressure, it is preferable to support the membrane by a framework in order to maintain the shape of the VRA. Recently, a titanium framework reinforced ultrafine titanium membrane was developed by laser processing technology. The technique allows microperforations to be made (φ20 μm) into a titanium membrane, which is expected to prevent fibrous tissue ingrowth from outside the membrane. In addition, significant bone regeneration has been confirmed on ridge defects in previous animal studies. However, the membrane tends to crumple during the bending process because it is very thin (20 μm), so the bending procedures are technically sensitive. Since this titanium honeycomb membrane was first approved for clinical use in Japan, no international clinical reports have been published. The purpose of this case report is to describe a technical note for a three- dimensional curvature bending method in VRA using the newly developed honeycomb structure Ti-membrane.