Abstract
Objective: Information about full-digital protocols for bite registration with intraoral scanners on multiple implants in the edentulous jaw is scarce. The purpose of this comparative in vivo study was to investigate the reliability and time efficiency of a novel full-digital bite registration technique for the manufacture of full-arch maxillary fixed implant prostheses. Material and methods: In ten patients, a full-arch maxillary fixed implant prosthesis was manufactured on multi-unit abutment level through an analog prosthetic workflow. The bite registration was performed with use of a screw-retained polymethyl methacrylate (PMMA) verification jig with detachable wax rim. To articulate the definitive edentulous maxillary implant cast in centric relation at the appropriate occlusal vertical dimension (OVD) to the mandibular antagonist cast, a type II articulator (Artex, Amann Girrbach) was used. Three to six months later, a full-digital bite registration was performed with use of dual-function scan bodies and bilateral connected bite pillars. The bite pillars screwed into the scan bodies were used to adjust and articulate the edentulous maxillary implant arch to the mandibular antagonist arch at the defined OVD. Treatment time for analog and digital bite registration technique was measured in each patient. The reliability of the digital bite registration technique was evaluated by 3D comparison of two sets of stereo lithographic (STL) files obtained from each patient. The three-dimensional deviation was defined along the X-, Y- and Z-axes (Geomagic Control X, 3D Systems Inc., Rock Hill, SC, USA). Results: The treatment time for digital bite registration using dual-function scan bodies and bite pillars was significantly shorter than analog bite registration with verification jig and wax rim (60.30%, SD 5.72%). Minor differences between the two techniques were observed with a linear deviation range of 1115 µm (SD 668 µm) overall, 46.2 µm (SD 731.3 µm) along the X-axis, −200.3 µm (SD 744.3 µm) along the Y-axis and 67.1 µm (SD 752.2 µm) along the Z-axis. Bilateral balanced contacts were registered in all patients during full-digital bite registration. Conclusions: The novel digital bite registration technique with dual-function scan bodies and bite pillars allows for a full-digital workflow for full-arch implant supported restorations. The digital bite workflow was 60% faster, and the overall deviation was around 1 mm, which can be considered clinically acceptable.
Keywords: bite registration, implants, full-arch, complete arch, digital impression, intraoral scan, digital workflow, bite pillar, dual function scan body
1. Introduction
Mounting an edentulous cast at the appropriate occlusal vertical dimension (OVD) and in centric relation (CR) is a crucial step in the rehabilitation of edentulous patients [1,2], certainly for the manufacture of a full-arch fixed implant prosthesis [3]. The correct OVD is determined by the rest position of the mandibular arch [4,5,6,7] and is defined by the point at which prosthetic tooth contact is made along the arc in centric occlusion (CO) or retruded contact position (RCP) [8]. The retruded contact position (RCP) was first introduced in 1952 in Posselt’s sagittal envelope of mandibular border movements’ as a relatively reproducible maxillomandibular relationship and plays a key role for mounting casts on an articulator [9,10,11,12].
Because occlusion has a biological adaptability and is not constant, we may speak of a range of CO positions acceptable for prosthetic rehabilitation. This freedom in centric was first described in 1969 by C. H. Schuyler as a flat area (500–1000 µm) created between centric relation and centric occlusion positions on the occlusal surfaces, from hinge position to habitual intercuspal position without any change in OVD [13]. To obtain a consistent CO registration, some authors recommended using mandibular guidance from the operator, chin point guidance, bi-manual manipulation or the use of an anterior jig [8,12].
A common registration technique for mounting the edentulous implant cast for a full-arch fixed implant prosthesis is the use of a screw-retained wax rim. This technique ensures a transfer of the implant cast at the correct vertical dimension (OVD) in centric relation (CR) to the articulator. Alternatively, a detachable wax rim supported by a verification jig can be made. This simplifies the procedure and avoids the entrapment of wax in the screw-access holes. In addition, the verification jig serves as a verification of the accuracy of the master cast. Other options for bite registration involve the use of a duplicated denture with acrylic resin as a custom impression tray, or even a duplicated denture with impression material [14,15,16,17]. Nevertheless, bite registration materials and methods should be selected carefully for implant-supported fixed prostheses [18].
The dynamic registration of Gothic arch tracing was first described in 1947 by Aprile and Salzar [19]. This method was found to be more technique sensitive and required more chair-side time both for the dentist and the patient. There was also a greater risk of incorporating errors due to mishandling of the device and fatigue of the jaw muscles from repeated efforts to guide the mandibular movements [20]. In case of an implant-supported prosthesis, healing abutments can be used to stabilize a record base for accurate Gothic arch tracing [21]. However, the use of auxiliary instruments is a drawback for inexperienced dentists to perform an accurate bite registration [20].
In digital workflow, the registration of the correct occlusion and manufacture of the prosthesis without physical casts and wax rim is difficult [22]. A full-digital workflow has been described for partial edentulous cases [23] but is still challenging for full edentulous cases.
For dentate cases, full-digital techniques for mounting a full-arch intraoral scan on a virtual articulator were described in the literature in several clinical case reports [15,24,25,26]. Hong et al. describes a technique to determine the sagittal condylar inclination (SCI) using CBCT data and intraoral scan data of the protrusive interocclusal position [27]. However, these techniques require the presence of teeth for superimposing.
Some authors suggest scanning the provisional restoration to superimpose with the scan bodies in the intraoral scan [17,28,29]. This requires, however, the presence of a provisional restoration that was made in a conventional way [18,30]. Another approach is to section the anatomical-shaped surgical guide and use it as a quadrant support while scanning the scan bodies and jaw relation in the contralateral quadrant [31]. Some authors have proposed the use of a custom scanning device, which is a printed or milled copy of the patient’s denture, which contains perforations at the implant locations. This allows the scan bodies to perforate and be scanned together with the custom device. Since most of the outline of this custom scanning device is identical to the complete denture, it provides a stable occlusion and correct OVD to register the maxillomandibular relationship. Although these concepts provide a solution to perform the digital workflow in edentulous arches, physical auxiliary instruments are still necessary [17,32]. A more invasive option is to place additional reference pins or mini-implants in the bone, which serve as markers for superimposing different scans [33,34,35]. Although these techniques have been successfully used in clinical studies, they require additional treatment steps or appliances and are therefore not always applicable in daily practice.
The aim of this study was to validate a novel technique for full-digital bite registration with a dual function scan body system providing dual functionality on multiple implants in the edentulous jaw. The first null hypothesis is that there is no difference between the digital and analogue bite registration in terms of treatment time. The second null hypothesis is that the CR position could be achieved at a pre-defined OVD within a clinically acceptable range of 1 mm in all axes.
2. Materials and Methods
2.1. Design of the Study
In ten patients, a full-arch maxillary fixed implant prosthesis was manufactured on multi-unit abutment level through an analog prosthetic workflow. In seven patients, the prosthesis was manufactured on 6 maxillary implants. In the other patients, 4, 5 and 7 maxillary implants were used to support a full-arch fixed implant prosthesis.
In all patients, multi-unit abutments (Medentika, Hügelsheim, Germany) were installed at a torque value of 15 Ncm prior to the full-arch impression. The bite registration was performed with use of a screw retained verification jig and a detachable wax rim (Figure 1a,b). A passive fit was observed in all patients.
Figure 1.
The analog bite registration was performed with use of a screw retained verification jig and a detachable wax rim: (a) screw retained PMMA (polymethyl methacrylate) verification jig on multi-unit abutment level with bilateral attachments (LEGO SYSTEM A/S, Billund, Denmark); (b) adjusted wax rim in CO position attached to the PMMA verification jig.
Treatment time for the analog bite registration technique was measured for each patient, starting from mounting the verification jig onto the multi-unit abutment level and ending with the manually mounted physical casts ready to send to the dental laboratory. To articulate the definitive edentulous maxillary implant cast at the appropriate occlusal vertical dimension (OVD) in centric relation to the mandibular antagonist cast, a type II articulator (Artex, Amann Girrbach) was used in the dental laboratory. A stopwatch (CASIO HS-80TW-1EF, CASIO COMPUTER CO., LTD., Shibuya-ku, Tokyo, Japan) was used to record the clinical time required for the two bite registration methods. Time was recorded by an independent investigator who was informed about the study protocol before study initiation.
Three to six months later, an intraoral scan of the maxillary arch with the full-arch fixed implant prosthesis in place was taken and saved in pre-preparation mode (3Shape Dental Desktop 1.7.9.1, 3Shape, Copenhagen, Denmark) (Figure 2a,b). The patient was asked to close, and the distance between a pen dot on the patient’s nose and chin was measured with a digital caliper (Figure 3).
Figure 2.
(a) Intraoral clinical view 4 months after installation of the maxillary full-arch fixed implant prosthesis on multi-unit abutment level. (b) The maxillary scan with the full-arch fixed implant prosthesis was saved in pre-preparation mode (3Shape Dental Desktop 1.7.9.1, 3Shape, Copenhagen, Denmark).
Figure 3.
The patient was asked to close with the full-arch fixed implant prosthesis in place, and the distance between a pen dot on the patient’s nose and chin was measured with a digital caliper.
For each implant position in the full-arch maxillary fixed implant prosthesis, a cut-out diameter of 6 mm was set in the intraoral scan. Next, the mandibular arch was scanned, and the bite was registered by taking two buccal scans, left and right, while the patient closed with the fixed prosthesis still in place. After disconnecting the full-arch fixed implant prosthesis, the dual-function scan bodies were installed. The maxillary scan was finalized by scanning the cut-out regions (Figure 4a,b) and registering the positions of the scan bodies. The maxillary scans were now aligned with the bite-scan, thereby positioning the maxilla with scan bodies in the original maxillomandibular relationship as determined by the analog bite registration, as used to create the current prosthesis (Figure 5).
Figure 4.
Subsequent to the intraoral scan of the maxillary arch with the full-arch fixed implant prosthesis: (a) a cut-out diameter of 6 mm was set for each implant position; (b) scan parts of dual-function scan bodies were installed and the maxillary scan was finalized by scanning the cut-out regions.
Figure 5.
The bite registration was performed with two buccal bite-scans tracing the full-arch maxillary fixed implant prosthesis and the mandibular antagonist arch (3Shape Dental Desktop 1.7.9.1, 3Shape, Copenhagen, Denmark). Consequently, the scan body positions are linked to the original maxillomandibular relationship as determined by the analog bite registration.
In a second session during the same visit, a new case was created in the intraoral scanner software (3Shape Dental Desktop 1.7.9.1, 3Shape, Copenhagen, Denmark), and the maxillary arch was scanned with the scan parts of the dual-function scan bodies on multi-unit abutment level (Figure 6).
Figure 6.
Intraoral scan of the maxillary arch with the scan parts of the dual-function scan bodies during the second scan session (3Shape Dental Desktop 1.7.9.1, 3Shape, Copenhagen, Denmark).
The digital bite registration started with the insertion of bite pillars into the screw holes of the scan parts of the dual-function scan bodies (Figure 7). Bite pillar prototypes of 3 different lengths were fabricated in PEEK material and were available for this study. These bite pillar prototypes allow for a maximal extension up to 7 mm from the upper surface of the scan part (Figure 8). The defined OVD, set by the extra oral marks, was obtained by adjusting the bite pillars at the desired position in contact with the opposing arch. Two lateral bite-scans were taken to complete the digital bite registration (Figure 9a,b).
Figure 7.
Bite pillars inserted into the screw holes of the scan parts of the dual-function scan bodies mounted on multi-unit abutment level, adjusted at the desired occlusal vertical dimension (OVD).
Figure 8.
Dual-function scan bodies on multi-unit abutment level (MU). The screw channel of the scan body contains a screw-thread to attach the bite pillar and to adjust it to the correct vertical height.
Figure 9.
(a) Right lateral side with a stable contact on four bite pillars screwed into the scan parts of the dual-function scan bodies at the desired OVD. (b) View on screen after digital bite registration at the right lateral side (3Shape Dental Desktop 1.7.9.1, 3Shape, Copenhagen, Denmark).
The treatment time for the digital bite registration technique was recorded from the installation of the dual-function scan bodies at a torque value of 10 Ncm, installing/adjusting the bite pillars and the registration of 2 lateral bite-scans. The treatment time ended when the digital casts were aligned in the intraoral scanner software and ready to be sent to the dental laboratory.
2.2. Data Definition
For each patient, 2 STL-sets were collected. The first STL-set (T1) is the scan data based on the analog bite registration and the current prosthesis. It contains an intraoral scan of the maxillary arch with the established full-arch fixed implant prosthesis and the mandibular antagonist at the maxillomandibular relationship as determined by the analog bite registration linked with an intraoral scan of the maxillary dual-function scan bodies (Figure 10).
Figure 10.
STL-set T1: Scan data of the analog bite registration. A digital impression of the maxillary arch with the established full-arch fixed implant prosthesis after 4 months in situ (transparently yellow) combined with a digital impression of the maxillary dual-function scan bodies, a digital mandibular antagonist impression and two buccal bite-scans (Geomagic Control X, 3D Systems Inc., Rock Hill, SC, USA).
The second STL-set (T2) is the scan data of the digital bite registration and contains an intraoral scan of the maxillary arch with only the dual-function scan bodies, the mandibular antagonist and two buccal bite-scans (left and right) with the adjusted bite pillars at the appropriate OVD (Figure 11).
Figure 11.
STL-set T2: Scan data of the digital bite registration. A digital impression of the maxillary arch with dual-function scan bodies, a digital mandibular antagonist impression and two bilateral buccal bite-scans with adjusted bite pillars inserted into the screw holes of the dual-function scan bodies (Geomagic Control X, 3D Systems Inc., Rock Hill, SC, USA).
2.3. Linear Measurements
A “best-fit” algorithm based on the mandibular arch was performed (Geomagic Control X, 3D Systems Inc., Rock Hill, SC, USA) to align both datasets. To compare the results of data sets T1 and T2, the X-, Y- and Z-axes were equated to enable future interpretation and analysis.
Occlusal plane was defined as XY-axis, with the origin between tooth 41 and 31. To ensure that the direction on the X-axis was the same within the first and second quadrant, the absolute value of the X-axis was used for the measurements.
The deviation along the X-axis represented a medio-lateral movement between the two CO positions. A positive X-value means a more lateral position of the digital bite registration in comparison to the analog bite registration.
Deviation along the Y-axis represented a dorso-ventral movement between the two CO positions. A positive Y-value means a more dorsal position of the digital bite registration in comparison to the analog bite registration.
Deviation along the Z-axis represented a caudo-cranial movement between the two CO positions. A positive Z-value means a more cranial position of the digital bite registration in comparison to the analog bite registration.
For each patient, 10 analytical points were determined on the scan bodies in the intraoral maxillary scan. First, all mesio-buccal corners were determined, followed by the mesio-lingual corners and (in one patient with four maxillary bone level implants) the disto-buccal corners. Numerical identification of each analytical point was performed along the X-, Y- and Z-axes (Figure 12), and the overall 3D deviation was calculated for each patient. In addition, the absolute deviation was recorded on all axes to determine the true linear distortion.
Figure 12.
For each patient, 10 analytical points were added to different scan body positions in the maxillary arch. Numerical identification of each analytical point was performed along the X-, Y- and Z-axes (Geomagic Control X, 3D Systems Inc., Rock Hill, SC, USA).
2.4. Statistical Analyses
Normality was checked with QQ plots, histograms, boxplots and the Shapiro–Wilk test. The Shapiro–Wilk test was not significant for both the linear measurements and the treatment time. One sample t test was used to compare the linear measurements. All statistical analyses were performed using SPSS 27, with the level of significance set at p < 0.05. Based on a mean difference of 1mm, the sample size was 10 to achieve a power of 80%.
3. Results
The mean treatment time for the analog bite registration technique was 19:00 min (SD 2:49 min; range 13:22–22:36 min) and 7:29 min (SD 1:19 min; range 5:02–9:06 min) for the digital registration with dual-function scan bodies and bite pillars. The mean time gain was 11:30 min (SD 2:21 min; range 8:20–15:19 min) or 60.36% (SD 5.58%). The difference is statistically significant (p < 0.001) (Figure 13).
Figure 13.
Time efficiency of digital vs. analog bite registration technique.
Bilateral balanced CO positions were registered in all patients during digital bite registration on at least one bite pillar per quadrant. The mean percentage of scan bodies establishing a stable contact with the antagonistic dentition was 69% (range 50–100%) per patient.
The mean overall 3D deviation between the analog and digital technique was 1115 µm (SD 668 µm, range 150–3160 µm). The mean linear deviation was 46 µm (SD 731 µm, range −2271–2135 µm) along the X-axis, −200 µm (SD 744 µm, range −2361–1376 µm) along the Y-axis and 67 µm (SD 752 µm, range −1660–1270 µm) along the Z-axis (Table 1). Only the deviation along the Y-axis was significant (p = 0.008).
Table 1.
Description and p values for all results.
| Mean (µm) | Standard Deviation (µm) | Minimum (µm) | Maximum (µm) | 95.0% Lower CL for Mean (µm) | 95.0% Upper CL for Mean (µm) | p Value | |
|---|---|---|---|---|---|---|---|
| Y-axis | 200 | 744 | −2.361 | 1.376 | −348 | −53 | 0.008 |
| Z-Axis | 67 | 752 | −1.660 | 1.269 | −82 | 216 | 0.374 |
| X-axis | 46 | 731 | −2.271 | 2.135 | −99 | 191 | 0.529 |
| Absolute Y-axis | 611 | 470 | 10 | 2360 | 518 | 700 | 0.001 |
| Absolute Z-Axis | 630 | 410 | 10 | 1660 | 552 | 710 | 0.001 |
| Absolute X-axis | 470 | 560 | 10 | 2270 | 364 | 580 | 0.001 |
| Distance3D | 1115 | 668 | 150 | 3160 | 980 | 1246 | <0.001 |
The absolute linear deviation was 475 µm (SD 556 µm, range 10–2270 µm) along the X-axis, 611 µm (SD 467 µm, range 10–2360 µm) along the Y-axis and 633 µm (SD 407 µm, range 10–1660 µm) along the Z-axis (Table 1). These deviations were statistically significant along the X-axis (p < 0.001), Y-axis (p < 0.001) and Z-axis (p < 0.001). The mean absolute 3D deviation in the first quadrant was 1075 µm (SD 692 range 150–3160 µm) and in the second quadrant 1155 µm (SD 647, range 210–2700 µm), which was not statistically significant different (p = 0.594) (Table 1) (Figure 14). Both intra-observer (p = 0.386, ICC = 0.998) and inter-observer (p = 0.114, ICC = 0.945) reliability were high.
Figure 14.
Linear deviation along X, Y and Y-axis between analog and digital bite registration technique. Mean and error bars are shown, with the error bars representing 1 SD.
4. Discussion
The first null hypothesis of this study was rejected (p < 0.001), as the time to perform a digital bite registration with the novel technique was significantly shorter (60%) than the conventional analog bite registration. The second null hypothesis was also rejected, as the CR position could be achieved at a pre-defined OVD within a clinically acceptable range of 1 mm in all axes.
Although digital impressions have been proven to be as accurate as conventional impressions for tooth-supported and implant-supported fixed partial prostheses, full-arch implant-supported reconstructions are still challenging to manufacture through a digital workflow. The lack of reference points, due to the missing dentition and ridge resorption, affects the accuracy of the scanning procedure [36]. Recent research has also demonstrated that full-arch digital implant impressions can be made with sufficient accuracy to achieve a passive fit [37,38,39,40,41,42,43]. However, the bite registration still requires physical auxiliary tools, such as a bite rim or tooth guide.
The technique with the bite pillars simplifies the bite registration and alignment of the edentulous arch with scan bodies to the opposing jaw. Apart from the simplified digital registration, this approach also saves time by registering the bite in the same visit as the impression. Since the bite pillars are directly mounted onto the fixated scan bodies, no time is lost during the intraoral scanning procedure to attach or detach various components. The overall treatment time was reduced by more than 50%, resulting in a time gain of 11.30 min. The patients were treated by a clinician who has experience with both bite registration methods. One can expect a learning curve to adapt the digital protocol, which might require more time in the beginning.
Although the elimination of a physical cast and articulator will reduce shipping time and costs to the dental laboratory, this advantage was not included in this comparative study.
Recording the jaw relation is a fundamental and crucial step to provide a well-functioning restoration. An accurate registration minimizes the need for intraoral adjustments and can therefore reduce treatment time and costs. The novel digital bite registration technique is a static registration of the jaw relation, directly captured by an intraoral scanner, and may therefore result in a more anterior registration of the CO position compared to dynamic Gothic arch tracing. This was also observed in our study, where we noticed a significant anterior shift of 200 µm in the jaw relation.
The absolute 3D deviation was 475 µm, which is in line with the findings by Wong et al. [44], who reported distortions around 500 µm in the bite registration of three different intraoral scanners. Fortunately, because of the biological adaptability of the patient’s occlusion, a range of CO positions are acceptable for prosthetic rehabilitation. According to Schuyler et al. [13], the centric freedom is a flat area ranging from 500–1000 µm, arising between centric relationship and centric occlusion positions on the occlusal surfaces, from hinge position to habituated intercuspal position without any change in the OVD. The majority of the measured deviations between the analog and digital registration were within or even below this threshold. Therefore, the digital bite registration using the bite pillars can be considered accurate, despite some deviation, which will have little to no impact on oral functioning. Nevertheless, it has been shown that a total 3D deviation of 1 mm will have limited to no clinical impact on the outcome of the rehabilitation [11,12,13,14]. Small distortions may also be compensated during the CAD design stage or by correcting the occlusion of the restoration during try-in [44].
Intra-oral scanners demonstrate a median deviation between 28–91 µm for full-arch implant scans, depending on the scanning system [45]. Although this deviation also affects the accuracy of bite registration, the clinical impact will be less compared to the influence on the fit and marginal adaptation of the final prosthesis. Intraoral scanners register the static relationship of the maxillary and mandibular jaw with a similar or even better accuracy than the conventional physical interocclusal record [46,47,48,49,50]. Ren et al. found a mean distortion of 280 µm in occlusal relation for digital impressions of partially edentulous casts [51]. In comparison, Eriksson et al. reported a distortion varying from 170 to 2650 µm after mounting the gypsum casts the conventional way [52]. However, similar to the conventional bite registration, the clinician’s experience with the IOS system is critical for the accuracy when recording the CR position [50].
Edher et al. [53] observed a tilting effect of the complete-arch scan toward the site of the interocclusal registration scan. For quadrant scans, they found a higher sensitivity when capturing the CR position. In addition, Gintaute et al. [54] reported a lower precision of the bite registration of full-arch scans when the posterior occlusal relation was scanned in comparison to the anterior relation. In the current study, a digital bite-scan was taken on both sides of the jaws. Since there was no significant difference in the deviation between the first and second quadrant, one can assume that the alignment of the maxillary and mandibular scans with the bite-scan was correct and not tilted to one side.
An additional argument for the observed deviations may be related to the determination of the OVD using a digital caliper. This is not an accurate measurement method and will affect the distortion in all directions, although this has limited impact on the digital bite registration method.
The accuracy of intraoral scanning is influenced by various factors, such as operator experience [55,56,57], scanning device, scanning range, inter-implant distance and the scan body design [29,58]. The height of the basal scan part of the dual function scan body is a crucial factor in the digital bite registration process, since its amount of visibility will affect the accuracy of the implant position registration [59,60]. The initial prototypes of the dual-function scan bodies were designed and manufactured on implant level, under supervision of the inventor (P.N.) and often resulted in a deep submucosal placement of the scan body, with little visibility on the intraoral scan to perform a correct alignment in the CAD-software. Therefore, the use of multi-unit abutments is advocated, which will compensate for variations in the mucosal thickness and corrects the implant angulation when necessary.
Conversely, the suggested protocol also requires mouth closure at the correct OVD without interference of the scan bodies. Therefore, the length of the scan bodies should be limited. The height of the basal scan part of the scan body (=7.5 mm) was based on personal feasibility tests by the inventor (P.N.), who measured the length of 1600 screw-access channels in partial- and full-arch implant restorations from March 2015 to October 2017 [61]. In none of the reported cases in this comparative in vivo study, this led to an interference with the opposing arch, nor did it hamper the alignment in the intraoral scanner software (3Shape Dental Desktop 1.7.9.1, 3Shape, Copenhagen, Denmark).
The use of the bite pillars and dual-function scan bodies allows for a full-digital workflow, in which the restoration is designed and fabricated in a monolithic approach without the need for a 3D-printed cast. This will further simplify the treatment and reduce the costs.
Another advantage of the bite pillars is that patients do not have to bite in a moldable material. This decreases the risk for anterior displacement or fading from the hinge position. In particular, patients with strangulation reflex, restless patients or patients with a voluminous tongue will benefit from this approach (Figure 15 and Figure 16). Conversely, an irregular opposing dentition might prevent a stable support for the bite pillar or cause a deviation of the mandibular closure path. The clinician should pay attention to this and correct the contact if possible, which requires certain experience from the clinician. Similarly, sufficient bite pillars should be in contact with the opposing dentition, preferably in both quadrants of the arch, to provide stability. This might be a problem when several antagonistic teeth are missing. This technique might also be used for full mouth rehabilitation, when both arches are edentulous. In that case, however, opposing scan bodies and bite pillars need to be in contact or an additional bite registration paste should be used to fabricate an occlusal table. The latter, however, will hamper the registration procedure and reduce the precision.
Figure 15.
Female patient of 61 years old with severe crestal bone loss in the maxillary arch and voluminous tongue interposition. Long bite pillars are recommended to set the maxillary arch in the appropriate OVD to the mandibular antagonist arch.
Figure 16.
Same patient: A digital impression of the maxillary arch with dual-function scan bodies, a digital mandibular antagonist impression and two bilateral buccal bite-scans with adjusted bite pillars inserted into the screw holes of the dual-function scan bodies on multi-unit level (Geomagic Design X, 3D Systems Inc., Rock Hill, SC, USA).
5. Conclusions
The novel digital bite registration technique with dual-function scan bodies and bite pillars allows for a full-digital workflow for full-arch implant supported restorations. The digital bite workflow was 60% faster, and the overall deviation around 1 mm, which can be considered clinically acceptable.
6. Patents
This manuscript is related to United States patent application no. 16/339,394 published as 20190223990 for NUYTENS Philippe entitled “Scan post, bite pillar, reference pillar and related methods for recording dental implant position”.
Acknowledgments
The authors wish to thank and acknowledge Luc Nuytens, father of the author, for his technical support during the experimental phase of development of this novel technique for digital bite registration.
Author Contributions
Conceptualization, P.N.; Formal analysis, R.D. and S.V.; Investigation, P.N.; Methodology, R.D. and S.V.; Project administration, P.N.; Writing—original draft, P.N. and S.V.; Writing—review & editing, R.D. and S.V. All authors have read and agreed to the published version of the manuscript.
Institutional Review Board Statement
This study was approved by the Ethical Committee of Ghent University Hospital, Belgium.
Informed Consent Statement
Informed consent was obtained from all subjects involved in the study.
Data Availability Statement
Data are available from the corresponding author upon request.
Conflicts of Interest
The authors declare no conflict of interest.
Funding Statement
This research received no external funding.
Footnotes
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Data Availability Statement
Data are available from the corresponding author upon request.