使用纤维内布拉格传感器测量猪(Sus scrofa)门牙牙周空间的活体应变。

IF 1.5 4区 医学 Q2 ANATOMY & MORPHOLOGY
Tracy E. Popowics, Isabelle Hwang, Jason Lu, Tammy Nguyen, Morgan Sample, Anissa Sangster, Derrick Tang, Christopher R. Dennison, Dan L. Romanyk, Katherine Rafferty, Geoffrey Greenlee
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引用次数: 0

摘要

猪(Sus scrofa)的门齿与圆盘形鼻共同作用,以探索环境中潜在的食物。了解施加在牙齿上的机械负荷如何使牙周韧带(PDL)变形,对于确定牙周机械感受器在食物探索和进食过程中的作用非常重要。本研究的目的是使用光纤布拉格(FBG)传感器测量猪门牙牙周韧带空间内的活体应变。在唇侧牙周间隙内记录 FBG 应变时,猪的下颌中切牙经历了弹簧加载的舌侧倾斜。将 FBG 传感器放置在约 2-3 个月大的猪下颌中央门齿的牙周间隙中。弹簧载荷的大小和方向可模拟门牙与食物的接触。在使用负荷校准弹簧进行门牙翻转时,体外(N = 6)和体内(N = 6)在可比负荷水平下记录到的 FBG 应变在范围上重叠(-10-20 με)。在所有体内实验中,FBG 的峰值应变(即记录的最高应变值)与基线应变(即未施加弹簧载荷时的应变)之间的线性回归结果均显著(200 g 时的峰值应变与基线应变相比,p = .04;2000 g 时的峰值应变与基线应变相比,p = .03;2000 g 时的峰值应变与 200 g 时的峰值应变相比,p = .004)。这些线性关系表明,在每次实验中,不同弹簧载荷下测量到的最大应变存在可预测的差异。对峰值应变绝对值的弗里德曼检验证实,基线、200 克和 2000 克弹簧激活时的应变显著增加(p = .02)。在唇侧 PDL 空间记录到的主要是压缩应变,体内施加的弹簧载荷增加会导致 FBG 应变测量值增加。这些结果表明,FBG 传感器可以在体内用于评估咬合负荷通过牙周的传递。PDL 应变与机械感受器刺激有关,预计会影响门牙的功能形态。所观察到的应变总体水平较低,这可能与猪门牙的功能形态强健以及猪在探索食物过程中会遇到不同食物和基质的趋势相吻合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

In vivo measurement of strain in the periodontal space of pig (Sus scrofa) incisors using in-fiber Bragg sensors

In vivo measurement of strain in the periodontal space of pig (Sus scrofa) incisors using in-fiber Bragg sensors

The incisor teeth in pigs, Sus scrofa, function in association with a disc-shaped snout to explore the environment for potential food. Understanding how mechanical loading applied to the tooth deforms the periodontal ligament (PDL) is important to determining the role of periodontal mechanoreceptors during food exploration and feeding. The objective of this study was to use fiber Bragg (FBG) sensors to measure strain in vivo within the PDL space of pig incisors. The central mandibular incisors of pigs underwent spring loaded lingual tipping during FBG strain recording within the labial periodontal space. FBG sensors were placed within the periodontal space of the central mandibular incisors of ~2–3-month-old farm pigs. The magnitude and orientation of spring loads are expected to mimic incisor contact with food. During incisor tipping with load calibrated springs, FBG strains in vitro (N = 6) and in vivo (N = 6) recorded at comparable load levels overlapped in range (−10–20 με). Linear regressions between peak FBG strains, that is, the highest recorded strain value, and baseline strains, that is, strain without applied spring load, were significant across all in vivo experiments (peak strain at 200 g vs. baseline, p = .04; peak strain at 2000 g vs. baseline p = .03; peak strain at 2000 g vs. 200 g, p = .004). These linear relationships indicate that on a per experiment basis, the maximum measured strain at different spring loads showed predictable differences. A Friedman test of the absolute value of peak strain confirmed the significant increase in strain between baseline, 200 g, and 2000 g spring activation (p = .02). Mainly compressive strains were recorded in the labial PDL space and increases in spring load applied in vivo generated increases in FBG strain measurements. These results demonstrate the capacity for FBG sensors to be used in vivo to assess transmission of occlusal loads through the periodontium. PDL strain is associated with mechanoreceptor stimulation and is expected to affect the functional morphology of the incisors. The overall low levels of strain observed may correspond with the robust functional morphology of pig incisors and the tendency for pigs to encounter diverse foods and substrates during food exploration.

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来源期刊
Journal of Morphology
Journal of Morphology 医学-解剖学与形态学
CiteScore
2.80
自引率
6.70%
发文量
119
审稿时长
1 months
期刊介绍: The Journal of Morphology welcomes articles of original research in cytology, protozoology, embryology, and general morphology. Articles generally should not exceed 35 printed pages. Preliminary notices or articles of a purely descriptive morphological or taxonomic nature are not included. No paper which has already been published will be accepted, nor will simultaneous publications elsewhere be allowed. The Journal of Morphology publishes research in functional, comparative, evolutionary and developmental morphology from vertebrates and invertebrates. Human and veterinary anatomy or paleontology are considered when an explicit connection to neontological animal morphology is presented, and the paper contains relevant information for the community of animal morphologists. Based on our long tradition, we continue to seek publishing the best papers in animal morphology.
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