Searson / Gough / Hemmings Implantology in General Dental Practice

Chapter 1
History and Development of Dental Implants
Aim
The aim of this chapter is to familiarise the reader with the history and development of dental implants and with relevant terminology and implant characteristics. Outcome
After reading this chapter the reader should have an understanding of dental implants, their design and characteristics and the various components that are used in implant dentistry. Introduction
Tooth loss as a result of disease, trauma, failure to develop and the adverse consequence of partial dentures is common. It is not surprising, therefore, that the history of tooth replacement has been long and multifaceted. Depending on the degree of edentulism, several treatment options are available, including: no replacement removable partial dentures complete dentures conventional or adhesive bridgework implant-supported prostheses transplantation. The management of edentulism poses a challenge to the practitioner. Evidence from ancient civilisations has shown throughout history that man has tried to replace missing and lost teeth with various materials, including carved ivory, wood and bone. At times, natural teeth were extracted from paupers and casualties of war to replace missing teeth in the wealthy. It was not until the 19th century that experiments using different materials and designs of appliances to replace missing teeth were reported in the dental literature. Attempted replacements ranged from the use of root-form gold implants placed into sockets to iridium-platinum basket-type endosteal implants with screws. Before the 1950s implant placement was more of an art form than a science. It was not until the late 1970s/early 1980s that the use of dental implants became more scientific and implantology was recognised by the academic community. The two main research groups responsible for the underpinning science were Brånemark and co-workers in the late 1960s, and Schroeder and co-workers in the mid-1970s. Both research groups established that direct contact exists between bone and dental titanium implants and that this contact results in the clinical stability of an implant during loading. For this mode of anchorage, Brånemark and co-workers coined the term “osseointegration” in 1967. Osseointegration is the direct structural and functional connection between ordered living bone and the surface of a load-carrying implant. Osseointegration heralded a fundamental scientific shift in thinking, previous implants having tended to develop a fibrous attachment that, it was hoped, could serve the same purpose as the periodontal ligament. The periodontal ligament is a specialised structure that serves as an effective attachment mechanism, a shock absorber and a sensory organ. Furthermore, the periodontal ligament is capable of mediating bone remodelling, allowing tooth movement. Previous non-integrating forms of implants may have been anchored to bone by means of a surrounding sheath of pseudo periodontal ligament, but this fibrous sheath was a poorly differentiated layer of scar tissue. In most cases, loading and gradual widening of this led to loosening of the implant and subsequent implant failure (Fig 1-1). Fig 1-1 Radiograph of blade implant showing implant failure. Implants
There are three types of implants available: subperiosteal transosseous endosseous. Subperiosteal
This type of implant consists of a non-osteointegrated framework that rests on the surface bone of the mandible or maxilla. The framework is positioned beneath the mucosa with, typically, a number of posts penetrating the mucosa to support an overdenture. Subperiosteal implants were originally introduced in the 1940s and served patients well for many years. Unfortunately, problems experienced included infection, exteriorisation by the downgrowth of epithelium and damage to the underlying bone. In some cases the subperiosteal implant would submerge into the bone, making it extremely difficult to remove (Fig 1-2). Fig 1-2 (a) Subperiosteal implant and (b) radiograph showing extensive bone loss around a subperiosteal implant. Transosseous
The transmandibular staple is the most used form of transosseous implant, consisting of a gold plate fitted to the lower border of the mandible and posts placed directly through the mandible to provide support for some form of denture. This approach was suitable only for the mandible. Although some reports show good results over periods of up to 10 years, the use of transosseous implants has been largely discontinued (Fig 1-3 and Fig 1-4). Fig 1-3 Transosseous implant frame. Fig 1-4 Intraoral view of transmandibular staple implant. Endosseous
These implants can be placed in the maxilla or mandible through an intraoral incision in the mucoperiosteum. The shapes and construction of endosseous implants have varied over the years, but the past two decades have seen the most dynamic developments. The clinician may be bewildered by the variety of implant shapes and designs available. However, various groups have developed certain criteria that aid the selection of implant systems. For example, Albrektsson and co-workers (1986) proposed the following criteria for a successful implant: The freestanding implant should be rigid clinically. Radiographic examination does not reveal any peri-implant radiolucency. In clinical service radiographic vertical bone loss is less than 0.2mm each year. Absence of signs or symptoms of failure, including pain, infection, neuropathies, paraesthesia or violation of anatomical structures. A success rate of 85% at the end of a five-year observation period and 80% at the end of a 10-year period. Factors Influencing Implant Osseointegration
Osseointegration is a union between bone and the implant surface. It can be measured histologically as the proportion of the total implant surface that is in direct contact with bone. Different levels of bone contact may occur with implants of different materials. There are a number of factors that may influence the degree of osseointegration, relating to one of three parameters: implant design host site surgical technique. Implant Design
Most contemporary dental implants are made of commercially pure titanium, which has been shown to have excellent biocompatibility. Titanium is a light metal. When exposed to air, a surface oxide is rapidly formed. This layer of oxide determines the biological response. Commercially pure titanium is also highly resistant to corrosion. Other metals have been used for osseointegration, including zirconium, gold and titanium-aluminium-vanadium alloys. These alloys may strengthen the implant but have been shown to have relatively poor bone-to-implant contact. Implant design has a great influence on the stability and subsequent function of the implant in bone. The main parameters are implant shape, implant length, implant diameter and surface characteristics. Root-form implants, such as screws and cylinders, are the dominating implant designs today. Screw implants are considered to be superior to cylindrical ones in terms of initial stability and resistance to compression and tension stresses under loading (Fig 1-5). Fig 1-5 Screw-shaped implant with abutment and final prosthesis in position. Implant Length
Research findings have shown that shorter implants fail more often than longer implants. Implant length varies from 6–20mm. The most common lengths employed are between 8–15mm. It is good practice to use the longest implant that can be safely placed, with, wherever possible bicortical stability. Clearly, certain anatomical limitations exist, for example, in the posterior mandible behind the mental foramen. Implant Diameters
The diameter of most implants falls within the range of 3.3–6mm. Narrow diameter implants can be used in small spaces. Larger diameter implants may be used, in particular in posterior areas of the mouth and where there is poor quality bone. Surface Characteristics
It has been suggested that the quality of osseointegration is related to the physical and chemical nature of the surface of the implant. Surface characteristics may be altered by several means including: Machining – the surface is produced by precision milling with no subsequent finishing. Plasma-spraying – spraying with molten titanium modifies and increases the effective surface area of the implant. Machine grit-blasting – the implant surface is roughened by grit-blasting with titanium oxide particles. Acid-etching – the implant surface is chemically etched to increase the thickness of the oxide layer. Sand-blasting and acid-etching – sand-blasting followed by acid-etching to substantially increase surface area. Anodisation – the implant surface is electrically treated to increase the thickness of the oxide layer. Coating – the implant surface is coated with calcium phosphate hydrox-yapatite to produce a so-called bioactive surface to enhance bone-to-implant...