On the influence of micro-and macroscopic surface modifications on bone integration of titanium implants
Abstract
Background: Osseointegrated titanium implants are routinely used in clinical denstistry
as anchorage units for dental prostheses. Although the overall clinical results are good,
there are clinical situations when an optimized implant healing is desirable, for instance
in order to shorten healing periods and to allow immediate loading.
Aims: The present work was undertaken to study the influence of some micro- and
macroscopical surface modifications on the integration and stability of titanium implants
in bone. In addition, the aim was also to study the influence of a bone growth factor and
autogenous bone grafts on implant healing in bone defects.
Materials & Methods: The thesis is based on five experimental studies using a total of
12 mongrel dogs and 39 New Zealand White rabbits. In total, 327 screw-shaped implants
were evaluated with histology and biomechanical tests. The implants had either a turned
surface or had been treated with anodic oxidation to create a porous surface structure
(microscopic modification). A groove with various sizes was added to one thread flank of
oxidized implants (macroscopic modification) for comparison with implants without a
groove. Ground sections of the intact bone-titanium interface were prepared for light
microscopy and quantitative morphometry. A micro-CT technique was used for 3D
visualisation of the bone in relation to the implant surface. Implant stability was measured
with removal torque (RTQ) tests and resonance frequency analysis (RFA) measurements.
Results: Turned and oxidized implants were placed in the dog mandible with
circumferential defects which were filled with dog BMP+ carrier, carrier alone, autogenous
bone chips or nothing. No differences in histological response and implant stability were
seen between the different materials and controls after 4 and 12 weeks of healing. However,
oxidized implants shower a stronger bone tissue response and were significantly more
stable than turned implants after 4 weeks. A rabbit study demonstrated direct bone formation
at the surface of oxidized but not turned implants after 7, 14 and 28 days. A darkly stained
layer became populated with osteoblasts which produced osteoid towards the implant
surface whilst turned implants seemed to be integrated by approximation of bone from the
surrounding bone and marrow tissues. In paper III, an increased resistance to RTQ was
seen for oxidized implants with a 110μm wide and 70 μm deep groove as compared with
control implants without a groove after 6 weeks of healing. This was not observed for 200
μm wide grooves. Histology showed an affinity of bone formation to the grooves. Paper
IV evaluated the influence of three different groove sizes on implant stability as measured
with RTQ and RFA. The results confirmed that 110 μm grooves resulted in better stability
than implants with 80 μm or 160 μm wide or no grooves. Histology of RTQ specimens
revealed an increased incidence of bone fracture at the entrance of the groove as opposed
to a separation at the bone-implant interface with decreased groove width. Bone formation
had an affinity to the grooves which increased with decreased groove width. In paper V,
bone formation was seen to occur more frequently in grooves than on opposing flank
surfaces after 7, 14 and 28 days of healing in implant sites with small bone volumes.
Conclusions: The present thesis shows that both micro- and macroscopical surface
modifications have positive influences on the bone tissue response and stability of titanium
implants. It is suggested that this is due to a combination of (i) contact osteogenesis as
stimulated by the microtopography and (ii) guided bone formation as stimulated by the
macrotopography, which resulted in an improved mechanical interlocking between bone
and implant surface.
Parts of work
I. Salata LA, Miranda-Burgos P, Rasmusson L, Novaes Jr AB, Papalexiou V, Dahlin C, Sennerby L. Osseointegration of oxidized and turned implants in circumferential bone defects with and without adjunctive therapies. An experimental study on BMP-2 and autogenous bone graft in the dog mandible. Submitted. II. Miranda-Burgos P, Rasmusson L, Meirelles L, Sennerby L. Early bone tissue responses to oxidized and turned titanium implants in the rabbit tibia. Submitted. III. Hall J, Miranda-Burgos P, Sennerby L. Stimulation of directed bone growth at oxidized titanium implants by macroscopic grooves. An in vivo study. Clinical Implant Dentisty and Related Research 2005;7 (suppl 1): 76-82 IV. Miranda-Burgos P, Sennerby L, Meirelles L, Hall J. Influence of groove width on affinity for bone formation and stability of grooved oxidized screw-shaped titanium implants. A biomechanical and histological study in the rabbit. Submited. V. Miranda-Burgos P, Schupbach P, Hall J, Sennerby L. Early bone formation at grooved oxidized titanium implants. A descriptive light microscopic and micro-CT study in the rabbit. In manuscript
Degree
Doctor of Philosophy (Medicine)
University
Göteborg University. Sahlgrenska Academy
Institution
Inst of Clincial Sciences. Dept of Biomaterials
patricia.miranda-burgos@biomaterials.gu.se
Date
2007-01-31Author
Miranda Burgos, Patricia
Keywords
titanium
dental implants
surface modification
bone tissue
biomechanics
BMP-2
Publication type
Doctoral thesis
ISBN
91-628-6895-0
978-91-628-6895-6
Language
eng