Implants
Dental implants are synthetic structures for insertion into the bone and are normally similar in shape to the root of a tooth (cylindrical or conical). They are mainly used for intraoral anchorage of fixed or removable restorations (superstructure). In special cases they are also used for anchorage of orthodontic appliances or maxillofacial prostheses (epitheses).
Implants in the 21st century are rarely made from zirconium dioxide. In the majority of cases they are made from pure titanium. This light and stable metal is bioinert, apposition and deposition of bone is therefore possible. Rigid fixation of the implant by gap-free, bone growth on the surface, i.e. osseointegration, is vitally important for ensuring permanent stability during functional loading of implants. Suitable procedures for roughening, creating niches and increasing the surface area facilitate migration of living bone cells and ingrowth of bone into the implant surface. This also applies for the neck of the implant which, only during the very early stages of development, was finished to a smooth polished surface.
To prepare for implant placement, a narrow hole is first drilled in the bone, which is then widened incrementally using other drills (mainly in compact bone) and/ or bone condensing instruments (mainly in cancellous bone) in ascending diameter until the planned final diameter of the bone cavity is achieved. Manual or mechanical placement of the cylindrical-conical implant with external thread(s) is the same type of procedure as controlled insertion of a screw. Adequate primary stability can often be achieved by a slight press fit and self-tapping thread.
The upper edge of the implant, i.e. the platform, can be placed at bone or tissue level.
Titanium implants at bone level
Implants at tissue level
Healing may be submerged (under the densely sealed mucosa covering) or open (using intraoperative forming of a gingival collar).
There is often less bone volume available for implants due to bone resorption after tooth loss. Bone augmentation procedures are then used (e.g. GBR, guided bone regeneration) or smaller (e.g. reduced diameter) implants placed. Standard implants have a platform diameter of approx. 4 mm. The term for platform sizes that are much larger than this is "wide"; the term for much smaller platform sizes is "narrow" and even thinner implants are known as "mini-implants".
Modern dental implants are usually two-part. The implant (tooth root replacement) and abutment (core unit) have an interlocking and frictional connection. The internal conical connection with additional interlocking "tongue and groove" elements for providing rotational security has become the established design. Retention screws are tightened using defined torque to exclude the risk of movements, loosening and material overloading.
A modern implant
Though previously the fitting surface of the abutment always had the same diameter as the implant platform, modern abutments are often smaller in this region. This so-called "platform switching" is intended to improve bone preservation.
A latest generation implant
It is important to strive for as correct an anatomical emergence profile as possible to ensure the natural appearance of implant-supported restorations (red-white aesthetics) and healthy peri-implant conditions.
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Wax build-up technique Wax build-up technique The various anatomical structures (such as cusp tips and slopes as well as marginal ridges) are usually built up one after another by adding small portions of wax (often using differently coloured waxes for didactic purposes). The firm, special waxes first have to be melted at room temperature. This can be carried out by warming small portions on differently shaped working tips of hand instruments in an open flame (such as a gas burner) or using electrically heated instruments which provide for more accurate temperature control and avoid contamination (e.g. electric wax-knife, induction heaters, wax dipping units). The wax is applied drop-by-drop to ensure that the warmer molten wax added last fuses seamlessly with the firm, cooler material. After hardening, the wax pattern can be reduced by sculpting, milling guidance surfaces or drilling to add retainers. Modern procedures include flexible, occlusal preforms for adding contours to soft wax. In addition, wax preforms, such as for occlusal surfaces or bridge pontics, are available in various shapes and sizes. Recently, irreversible, light-curing materials have been introduced for use instead of reversible thermoplastic waxes. Wax preforms To ensure that the wax pattern can be released without being damaged, model surfaces, opposing dentition and preparations must be hardened/sealed with special lacquer (applied by spraying, brushing or dipping). These waxes are mostly relatively rigid/elastic after cooling. Attaching wax sprues to a removable framework supported on double crowns using a hand instrument When employing the lost wax technique, prefabricated wax sprues, bars and reservoirs are attached to the patterns. Once the pattern has been released and its sprues waxed onto the crucible former, it is invested in a casting ring with refractory investment material. The wax can then be burnt out residue-free and casting completed. Unlike standard wax build-up techniques, a diagnostic wax-up is not intended for fabricating an indirect restoration, but rather for simulating the appearance and/or external contouring for producing orientation templates. |