Comprehensive analysis of laserscanner validity used for measurement of wear

Hsu, Shu‐Min; Ren, F.; Abdulhameed, Nader; Kim, Mijin; Neal, Dan; Esquivel‐Upshaw, Josephine F.

doi:10.1111/joor.12778

Cited by 3 publications

(2 citation statements)

References 18 publications

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“…More recently, the assessment of in vivo wear has been conducted using laser scanner technology or profilometry with tooth replicates either in acrylic resin or stone (Heintze, Cavalleri, Forjanic, Zellweger, & Rousson, 2006;Mehl, Gloger, Kunzelmann, & Hickel, 1997;Pintado, Anderson, DeLong, & Douglas, 1997;Rodriguez & Bartlett, 2010;Rodriguez, Curtis, & Bartlett, 2009;Schlueter, Ganss, Sanctis, & Klimek, 2005). While this has proven to be effective, there are some errors involved in the replication process with the impression and the replicating materials (Hsu et al, 2019;Rodriguez & Bartlett, 2010;Segerström, Wiking-Lima de Faria, Braian, Ameri, & Ahlgren, 2018). Also, the resolution accuracy of the laser scanners varies from 5 to 20 μm and can affect the quantification of wear.…”

Section: Introductionmentioning

confidence: 99%

Novel methodology for measuring intraoral wear in enamel and dental restorative materials

Esquivel‐Upshaw

Hsu

Bohórquez

et al. 2020

Clinical & Exp Dental Res

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Objectives To test the hypotheses that (a) the chairside/handheld dental scanner combined with a metrology software will measure clinical wear in vivo in agreement with measurements from X‐ray computed microtomography and; (b) polished monolithic zirconia does not cause accelerated wear of opposing enamel. Materials and methods Thirty single crowns were randomized to receive a monolithic zirconia or metal‐ceramic crown. Two non‐restored opposing teeth in the same quadrants were identified to serve as enamel controls. After cementation, quadrants were scanned using an intraoral dental scanner. Patients were recalled at 6‐months and 1‐year for re‐scanning. Scanned images were compared using a metrology software to determine maximum vertical wear of teeth. The accuracy of the scanning measurements from this new method was compared with X‐ray computed microtomography (micro‐CT) measurements. Statistical analysis was performed using Mann–Whitney U test to determine significant differences between wear of enamel against zirconia, metal‐ceramic or enamel. Linear regression analysis determined agreement between measurements obtained using intraoral scanning and micro‐CT. Results Regression analysis demonstrated that there is a quantitative agreement between depth and volume measurements produced using intraoral scanning and the micro‐CT methodologies. There was no significant difference between the wear of enamel against polished monolithic zirconia crowns and enamel against enamel. Conclusions Intraoral scanning combined with a matching software can accurately quantify clinical wear to verify that monolithic zirconia exhibited comparable wear of enamel compared with metal‐ceramic crowns and control enamel. Agreement between the intraoral scanner and the micro‐CT was 99.8%. Clinical Trials.gov NCT02289781.

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Section: Introductionmentioning

confidence: 99%

Novel methodology for measuring intraoral wear in enamel and dental restorative materials

Esquivel‐Upshaw

Hsu

Bohórquez

et al. 2020

Clinical & Exp Dental Res

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“…After all scans at t0 were accomplished, wear areas were manually simulated using a diamond-bur (Ø1.2 mm, grit size 46 µm) [11]. In total, three stages of wear (t1-t3) were created successively at tooth 26 mesio-oral and tooth 27 disto-buccal (Figure 2).…”

Section: Digitization Of the Study Castmentioning

confidence: 99%

Measurement of Tooth Wear by Means of Digital Impressions: An In-Vitro Evaluation of Three Intraoral Scanning Systems

et al. 2021

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This in-vitro study aimed to investigate whether intraoral scanners (IOS) are suitable for wear measurement compared to optical profilometry (WLP). A zirconia cast representing the teeth (24–28) was fabricated. It was digitized six times using three different intraoral scanners, Cerec Omnicam AC (OC), Trios 3 (Tr3), and True Definition (TD). The scans were conducted at baseline (t0) and at three different stages of simulated wear (t1–t3), each at one wear-facet on FDI 26 and FDI 27. WLP was used as a reference method. Within each acquisition system, the maximum wear at each facet was analyzed by superimposing the STL data of t0 with t1–t3. A power analysis was performed (G*Power), and the Wilcoxon-signed-rank-test was used to evaluate whether there were statistically significant differences between the groups (Bonferroni corrected) (α = 0.05). At wear-facet FDI 27, differences from +4% t1 TD up to +19% t2 OC, corresponding to a metric value of 8 µm and 45 µm, were measured. At FDI 26 deviations between −2% t1 Tr3, and +10% OC and Tr3, were observed. Considering some limitations, the IOS are a promising alternative to wear measurement based on WLP due to its simple application to capture surface changes in a reasonable and quick way.

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Integration of Scanning Technology for Tool Wear Analysis in the Electrical Discharge Machining Process

Sabbar,

Khleif,

Albaghdadi

et al. 2024

Eng. Technol. Appl. Sci. Res.

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There is a direct correlation between surface roughness and electrode tool status in the Electrical Discharge Machining (EDM) process. The quality of the machined surface of workpieces is becoming even more critical in recent industries. In general, electrode wear evaluation plays a vital role in the EDM process, affecting the operation cost and the accuracy of the required dimensions and geometric shape. This study presents a new method to evaluate the copper electrode wear during machining AISI 1005 carbon steel in the EDM process using a 3D laser scanner that measures the lost volume of the electrode. The results of the proposed method were compared with those of the conventional method. Laser technology was used to accurately measure the dimensions and surface characteristics of the electrode by scanning the electrode surface and the electrode view topology before and after the machining process. The processed data was saved on a computer connected to the laser scan device, converted to STL files, and sent to a 3D system (Geomagic Control X software). This software utilizes accurate mathematical algorithms to determine the available volumetric differences in the electrode. The experiments used Design-Expert 13 software, selecting three machining parameters: Current (Ip), pulse on time (Ton), and pulse off time (Toff). The results showed that the Tool Wear Rate (TWR) obtained by the two methods showed a mean absolute deviation of 3.6%, with an insignificant error on the effect of the machining parameters on TWR (1.01% for Ip, 1.92% for Ton, and 2.29% for Toff).

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Comprehensive analysis of laserscanner validity used for measurement of wear

Cited by 3 publications

References 18 publications

Novel methodology for measuring intraoral wear in enamel and dental restorative materials

Novel methodology for measuring intraoral wear in enamel and dental restorative materials

Measurement of Tooth Wear by Means of Digital Impressions: An In-Vitro Evaluation of Three Intraoral Scanning Systems

Integration of Scanning Technology for Tool Wear Analysis in the Electrical Discharge Machining Process

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