3D surface defect map for assessing buccolingual profile of single tooth gaps following alveolar ridge preservation.

Leonardo Mancini, Shayan Barootchi, Miha Pirc, Enrico Marchetti, Ronald E Jung, Lorenzo Tavelli, Daniel S Thoma
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Abstract

Aim: A new, non-invasive approach suggests using single intraoral optical scanning to analyze the ridge profile of single-tooth gaps following alveolar ridge preservation in the absence of a baseline scan. This method involves creating a three-dimensional (3D) surface map to identify and assess contour changes and ridge profiles based on the adjacent teeth.

Materials and methods: The present study was designed as a cross-sectional pilot analysis on a convenience sample of patients undergoing alveolar ridge preservation. Intraoral optical scans were taken on 23 patients, capturing data from 30 edentulous sites. The digital models were then imported into an image analysis software for a 3D surface defect map analysis performed by one examiner. This analysis characterized the buccolingual profile of the single tooth gap relative to the adjacent teeth. 10 linear divergence points, spaced 0.5 mm apart in a corona-apical direction, were identified at the midfacial aspect of the sites. Based on these points the sites were plotted and grouped in three different buccolingual profiles (linear, concave, and convex). Clinical parameters including Keratinized mucosa Width (KMW), and soft tissue phenotype with Colorvue biotype probes were also recorded.

Results: Three different buccolingual patterns (linear, convex, and concave) were identified. Seven sites exhibited a linear profile, 10 sites displayed a concave shape, and 13 showed a convex profile. The linear profile had surface discrepancies similar to the neighboring teeth. In contrast, the convex profile revealed mid-buccal discrepancy localized only at the crestal aspect, while the concave had an extended divergence ranging from 1 to 5 mm below the soft tissue margin. Univariate and multiple logistic regression analyses did not reveal any statistically significant variables influencing profilometric analysis; however, when combining phenotype and KMW, thick phenotypes demonstrated a higher proportion of concavity (OR = 4.83) compared to thin ones, suggesting a significant trend. With every 1 mm of increase in KMW, the probability of showing a concavity decreased (p = 0.057).

Conclusion: A 3D surface defect map represents a useful tool for objectively quantifying ridge defects and profiles by assessing profilometric and surface differences compared to adjacent dentition using a single intraoral scan. This method also indicates that KMW may play a critical role in preventing concavity defects. The 3D defect map can guide decision-making during soft tissue augmentation procedures by emphasizing the specific location of the defect and providing more detailed insights into its localization. These parameters can enable the tailoring of flap management and soft tissue grafting strategies to address the patient's individual needs.

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三维表面缺陷图,用于评估牙槽嵴保留后单齿隙的颊舌侧轮廓。
目的:一种新的、非侵入性的方法建议在没有基线扫描的情况下,使用单次口腔内光学扫描来分析牙槽嵴保留后单牙间隙的牙嵴轮廓。这种方法包括创建一个三维(3D)表面图,根据邻牙识别和评估轮廓变化和牙脊轮廓:本研究旨在对接受牙槽嵴保留治疗的患者样本进行横断面试验分析。对 23 名患者进行了口内光学扫描,采集了 30 个缺牙部位的数据。然后将数字模型导入图像分析软件,由一名检查人员进行三维表面缺陷图分析。该分析描述了单个牙缝相对于邻牙的颊舌侧轮廓。在这些部位的面中部确定了 10 个线性分歧点,这些点在冠尖方向上的间距为 0.5 毫米。根据这些点将这些部位绘制成三种不同的颊舌侧剖面图(线形、凹形和凸形)。临床参数包括角化粘膜宽度(KMW)和使用 Colorvue 生物型探针的软组织表型:结果:确定了三种不同的颊舌形态(线形、凸形和凹形)。7 个部位呈现线形轮廓,10 个部位呈现凹形轮廓,13 个部位呈现凸形轮廓。线形轮廓的表面差异与邻近牙齿相似。相比之下,凸面轮廓显示的颊中部差异仅局限于嵴的一面,而凹面轮廓的差异则扩大到软组织边缘以下 1 到 5 毫米的范围。单变量和多重逻辑回归分析没有发现任何对轮廓测量分析有显著统计学影响的变量;但是,当结合表型和 KMW 时,厚的表型比薄的表型显示出更高的凹陷比例(OR = 4.83),这表明了一个显著的趋势。KMW 每增加 1 毫米,出现凹陷的概率就会降低(p = 0.057):三维表面缺损图是一种有用的工具,可通过口内扫描评估与邻牙相比的轮廓和表面差异,从而客观量化牙脊缺损和轮廓。这种方法还表明,KMW 可在预防凹陷缺陷方面发挥关键作用。三维缺损图通过强调缺损的具体位置并提供更详细的定位信息,可以指导软组织增量手术的决策。这些参数可以帮助定制皮瓣管理和软组织移植策略,以满足患者的个性化需求。
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