1. Diagnosis and tt planning in FDP-II
Dr Jitendra Rao
Dept of Prosthodontics

2. Indication for FDP/FPD
Mutilated crown or tooth
Missing tooth
Endodontically tt teeth
Discolored teeth
Fractured tooth
Spacing

3. Contraindication High caries index High DMF index
Unfavorable abutments
Age below 18yr of age
Medically compromised patients
Neurological patients
Xerostomic patients
Patients with radiotherapy and chemotherapy

4. Articulators: Articulators vary widely in the accuracy with which they reproduce the movements of the mandible.
Non-adjustable articulator: device/instrument that is capable of only a hinge opening
Semi-adjustable articulator:
Allows a close approximation of anatomic distance between the axis of rotation and the teeth
casts are mounted using facebow pproximate transverse horizontal axis, the radius of movement produced on the articulator will reproduce the arc of closure with relative accuracy and any resulting error will be slight
Inter condylar distances are adjustable to small, medium and large configurations

5. Fully adjustable articulator:
This type of articulator can be used for the fabrication of most single units and fixed partial denture
Use face bow-arbitrary
Arcon articulators e.g. Whip mix– used more for fixed restoration
Non arcon e.g Hanau series- used for complete denture
Fully adjustable articulator:
designed to reproduce the entire character of border movements, including immediate and progressive lateral translation, and the curvature and direction on condylar inclination
Inter condylar distance is completely adjustable
Face bow -kinematic

7. Locating the transverse hinge axis
axis of rotation that is as close as possible to the transverse horizontal axis of the patient’s mandible
The most accurate way to determine the hinge axis is by the “trial and error” method developed by McCollum and Stuart in 1921 (using a kinematic face bow).
Arbitrary face bows can also use but they must have an acceptable accuracy.
Caliper style ear piece face bows possess a relatively high degree of accuracy with 75% of the axes located by it falling within 6 mm of the true hinge axis

9. Single tooth restoration
INTRA CORONAL RESTORATIONS - depended on the strength of the remaining tooth structure for structural integrity e.g inlay,onlay
EXTRA CORONAL RESTORATIONS
If insufficient tooth structure exists to retain the restoration within the crown of the tooth, an extracoronal restoration, or crown is needed.
Partial veneer crown
Full metal crown

10. TREATMENT PLANNING FOR REPLACEMENT OF MISSING TEETH
Important ones are
Biomechanical factors
Periodontal factors
Esthetics
Financial factors
Patient’s wishes

11. Abutment Evaluation
Abutment is a tooth, portion of tooth or portion of a dental implant that supports or retain a prosthesis
Abutment teeth are called upon to withstand the forces normally directed to the missing teeth, in addition to those usually applied to the abutments
Whenever possible an abutment should be a vital tooth. However, a tooth that has been endodontically treated which is asymptomatic with radiographic evidence of a good seal and complete obturation of the canal can be used as an abutment. If the endodontically treated tooth does not have sound tooth

12. The roots and their supporting tissues should be evaluated for 3 factors:
Crown-root ratio
Root configuration
Periodontal ligament area

13. Ideal crown-root ratio for a tooth to be utilized as a fixed partial denture abutment

14. Studies by Klaffenbach in 1936 have shown that occlusal forces exerted against prosthetic appliances have been shown to be considerably less than that against natural teeth (about 160lb)
FPD against RPD  26.0lb
FPD against FPD  54.4 lb
FPD against natural teeth  150.0lb

15. Root configuration-

16. Periodontal ligament area- Johnston et al in 1971 in their statement designated as “Ante’s law” said that the root surface area of the abutment teeth had to equal or surpass that of the teeth being replaced with pontics

17. Jepsen in 1963 has reported areas of the root surfaces of the various teeth which is also termed as Jepsen’s rule
Root Surface Area (mm)
Teeth
Maxillary
Mandibular
Central Incisor
204
154
Lateral
179
168
Canine
273
268
First PM
234
180
Second PM
220
207
First Molar
433
431
Second Molar
426

18. Biomechanical Considerations
All fixed partial dentures, long or short spanned bend and flex under masticatory load
Bending or deflection varies directly with the cube of the length and inversely with the cube of occlusogingival thickness of the pontic
( D α L3 ) where D is defelection, L is length of the pontic span on given occlusogingival height
Compared with a fixed partial denture having a single tooth pontic span, a two tooth pontic span will bend 8 times as much
Double abutments are sometimes used as a means of overcoming problems created by unfavourable crown-root ratios and long span. There are several criteria that must be met, if a secondary abutment is to strengthen the fixed partial denture

19. SPECIAL PROBLEMS Pier abutments:
An edentulous space can occur on both sides of a tooth, creating a lone, free standing pier abutment
Physiologic tooth movement, arch position of the abutments and a disparity in the retentive capacity of the retainers can make a rigid 5-unit fixed partial denture as a less than ideal plan of treatment
Forces are transmitted to the terminal retainers as a result of the middle abutment acting as a fulcrum, causing failure of the weaker retainer

20. Pier abutment

21. The use of a non-rigid connector has been recommended to reduce this hazard
The most commonly used non-rigid design is a T shaped key that is attached to the pontic and a dove tail key way placed within a retainer
The key way of the connector should be placed within the normal distal contours of the pier abutment and the key should be placed on the mesial side of the distal pontic
Non rigid connector transfer shear stress to bone rather than connector as well as minimize mesiodistal torqueing of abutment

22. Tilted Molar Abutments
When the teeth are mesially tilted beyond an optimal degree of tilt deleterious forces act over the abutment causing vertical bone loss around the mesial portion of teeth thus further compromising periodontal support and weakening of the abutment
If these teeth are used as abutment for fixed partial dentures it will lead to failure of prosthesis
The over-all objective in molar uprighting is ideal positioning of the molar which will eventually become an abutment tooth for a fixed prosthesis. The ideal position will provide an optimal periodontal environment for the molar

24. A proximal half crown can be used as a retainer on the distal abutment
A proximal half crown can be used as a retainer on the distal abutment. This preparation design is a 3 ¼ crown that has been rotated 90°. It can be used only if the distal surface is untouched by caries
A telescoping crown and coping can also be used as a retainer for the tilted molar. A full crown preparation with heavy reduction is made to follow the long axis of the tilted molar. An inner coping is made to fit the tooth preparation. The proximal half crown that will serve as the retainer for the FPD is fitted over the coping
A non-rigid connector is another solution to the problem. A full crown preparation is done on the tilted molar, with its path of insertion parallel with the long axis. A box form is placed on the distal surface of the premolar to accommodate a keyway in the distal of the premolar crown

25. Cantilever FPDs
A cantilever FPD is one that has an abutment or abutments at one end only, with the other end of the pontic remaining unattached. This is a potentially destructive design with the lever arm created by the pontic
Abutment teeth for cantilever FPDs should be evaluated for lengthy roots with a favorable configuration, good crown root ratios and long clinical crowns.

27. Canine Replacement FPD/ Canine Rule
This is a problem because often the canine lies outside the interabutment axis
The abutments are the lateral incisor, usually the weakest in the entire arch and the first premolar, the weakest posterior tooth
A FPD replacing maxillary canine is subjected to more stress than that replacing a mandibular canine, since forces are transmitted outward on the maxillary arch. So the support from secondary abutments will have to be considered.

28. Books
Rosensteil
Shillingburg