4.7 Article

Nonuniformity in Periodontal Ligament: Mechanics and Matrix Composition

Journal

JOURNAL OF DENTAL RESEARCH
Volume 100, Issue 2, Pages 179-186

Publisher

SAGE PUBLICATIONS INC
DOI: 10.1177/0022034520962455

Keywords

dense collar; furcation; structure; immunohistochemistry; mass spectrometry; mechanics

Funding

  1. NIA NIH HHS [R00 AG063896, K99 AG063896] Funding Source: Medline
  2. NIDCR NIH HHS [R00 DE025053, K99 DE025053] Funding Source: Medline
  3. NINDS NIH HHS [P30 NS072030] Funding Source: Medline

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The study reveals significant differences in structure and mechanical properties between the furcation and collar regions of the periodontal ligament (PDL). The dense collar region is stiffer and acts as a scaffold for tooth stabilization, while the furcation region contains more proteins related to remodeling and load transfer, suggesting a critical role in these processes.
The periodontal ligament (PDL) plays a critical role in providing immediate response to abrupt high loads during mastication while also facilitating slow remodeling of the alveolar bone. The PDL exceptional functionality is permitted by the unique nonuniform structure of the tissue. Two distinct areas that are critical to PDL function were previously identified: the furcation and the dense collar. Despite their hypothesized functions in tooth movement and maintenance, these 2 regions have not yet been compared within the context of their native environment. Therefore, the objective of this study is to elucidate the extracellular matrix (ECM) structure, composition, and biomechanical function of the furcation and the collar regions while maintaining the 3-dimensional (3D) structure in the murine PDL. We identify significant difference between the collar and furcation regions in both structure and mechanical properties. Specifically, we observed unique longitudinal structures in the dense collar that correlate with type VI collagen and LOX, both of which are associated with increased type I collagen density and tissue stiffness and are therefore proposed to function as scaffolds for tooth stabilization. We also found that the collar region is stiffer than the furcation region and therefore suggest that the dense collar acts as a suspense structure of the tooth within the bone during physiological loading. The furcation region of the PDL contained more proteins associated with reduced stiffness and higher tissue remodeling, as well as a dual mechanical behavior, suggesting a critical function in loads transfer and remodeling of the alveolar bone. In summary, this work unravels the nonuniform nature of the PDL within the 3D structural context and establishes understanding of regional PDL function, which opens new avenues for future studies of remodeling, regeneration, and disease.

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