Sage Journals: Discover world-class research

Abstract

In vitro models are invaluable tools for deconstructing the biological complexity of the periodontal ligament (PDL). Model systems that closely reproduce the 3-dimensional (3D) configuration of cell–cell and cell–matrix interactions in native tissue can deliver physiologically relevant insights. However, 3D models of the PDL that incorporate mechanical loading are currently lacking. Hence, we developed a model where periodontal tissue constructs (PTCs) are made by casting PDL cells in a collagen gel suspended between a pair of slender, silicone posts for magnetic tensile loading. Specifically, one of the posts was rigid and the other was flexible with a magnet embedded in its tip so that PTCs could be subjected to tensile loading with an external magnet. Additionally, the deflection of the flexible post could be used to measure the contractile force of PDL cells in the PTCs. Prior to tensile loading, second harmonics generation analysis of collagen fibers in PTCs revealed that incorporation of PDL cells resulted in collagen remodeling. Biomechanical testing of PTCs by tensile loading revealed an elastic response at 4 h, permanent deformation by 1 d, and creep elongation by 1 wk. Subsequently, contractile forces of PDL cells were substantially lower for PTCs under tensile loading. Immunofluorescence analysis revealed that tensile loading caused PDL cells to increase in number, express higher levels of F-actin and α–smooth muscle actin, and become aligned to the tensile axis. Second harmonics generation analysis indicated that collagen fibers in PTCs progressively remodeled over time with tensile loading. Gene expression analysis also confirmed tension-mediated upregulation of the F-actin/Rho pathway and osteogenic genes. Our model is novel in demonstrating the mechanobiological behavior that results in cell-mediated remodeling of the PDL tissue in a 3D context. Hence, it can be a valuable tool to develop therapeutics for periodontitis, periodontal regeneration, and orthodontics.

Keywords

in vitro techniques PDL bioengineering regeneration mechanical stress collagen

Get full access to this article

View all access options for this article.

References

Aveic

Craveiro

Wolf

Fischer

. 2021. Current trends in in vitro modeling to mimic cellular crosstalk in periodontal tissue. Advanced Health Mater. 10(1):e2001269.

Beertsen

McCulloch

Sodek

. 1997. The periodontal ligament: a unique, multifunctional connective tissue. Periodontol 2000. 13(1):20–40.

Berkovitz

. 1990. The structure of the periodontal ligament: an update. Eur J Orthod. 12(1):51–76.

Bielawski

Leonard

Bhandari

Murry

Sniadecki

. 2016. Real-time force and frequency analysis of engineered human heart tissue derived from induced pluripotent stem cells using magnetic sensing. Tissue Eng Part C. 22:932–940.

Bremner

Goldstein

Higashi

Sniadecki

. 2022. Engineered heart tissues for contractile, structural, and transcriptional assessment of human pluripotent stem cell-derived cardiomyocytes in a three-dimensional, auxotonic environment. In: Coulombe

KLK

Black

III , editors. Cardiac tissue engineering: methods and protocols. New York (NY): Springer US. p. 87–97.

Cattaneo

Dalstra

Melsen

. 2005. The finite element method: a tool to study orthodontic tooth movement. J Dent Res. 84(5):428–433.

Chaudhuri

Cooper-White

Janmey

Mooney

Shenoy

. 2020. Effects of extracellular matrix viscoelasticity on cellular behaviour. Nature. 584(7822):535–546.

Feng

Yang

Liu

Wang

Song

Cao

Gan

Kou

Zhou

. 2016. PDL progenitor–mediated PDL recovery contributes to orthodontic relapse. J Dent Res. 95(9):1049–1056.

Fill

Carey

Toogood

Major

. 2011. Experimentally determined mechanical properties of, and models for, the periodontal ligament: critical review of current literature. J Dent Biomech. 2011:312980.

10.

Gauthier

Jeannin

Attik

Trunfio-Sfarghiu

Gritsch

Grosgogeat

. 2021. Tissue engineering for periodontal ligament regeneration: biomechanical specifications. J Biomech Eng. 143(3):030801.

11.

Green

Hembry

Atkinson

Reynolds

Meikle

. 1990. Immunolocalization of collagenase and tissue inhibitor of metalloproteinases (TIMP) in mechanically deformed fibrous joints. Am J Orthod Dentofacial Orthop. 97(4):281–288.

12.

Hirashima

Ohta

Kanazawa

Okayama

Togo

Uchimura

Kusukawa

Nakamura

. 2016. Three-dimensional ultrastructural analysis of cells in the periodontal ligament using focused ion beam/scanning electron microscope tomography. Sci Rep. 6(1):1–9.

13.

Huang

Sanaei

Verdurmen

WPR

Yang

Walboomers

. 2023. The application of organs-on-a-chip in dental, oral, and craniofacial research. J Dent Res. 102(4):364–375.

14.

Huang

Lin

Zhu

Xiao

Zhang

. 2023. Collagen hydrogel viscoelasticity regulates MSC chondrogenesis in a ROCK-dependent manner. Sci Adv. 9(6):eade9497.

15.

Huang

Liu

Cha

Yuan

Kelly

Singh

Hyman

Brunski

Helms

. 2016. Mechanoresponsive properties of the periodontal ligament. J Dent Res. 95(4):467–475.

16.

Janjić

Nemec

Maaser

Sagl

Jonke

Andrukhov

. 2023. Differential gene expression and protein-protein interaction networks of human periodontal ligament stromal cells under mechanical tension. Eur J Cell Biol. 102(2):151319.

17.

Jónsdóttir

Giesen

Maltha

. 2006. Biomechanical behaviour of the periodontal ligament of the beagle dog during the first 5 hours of orthodontic force application. Eur J Orthod. 28(6):547–552.

18.

Kang

Lee

Ahn

Kim

Kang

. 2013. Bioinformatic analysis of responsive genes in two-dimension and three-dimension cultured human periodontal ligament cells subjected to compressive stress. J Periodontal Res. 48(1):87–97.

19.

Kook

Jang

Lee

. 2011. Involvement of JNK-AP-1 and ERK-NF-κB signaling in tension-stimulated expression of type I collagen and MMP-1 in human periodontal ligament fibroblasts. J Appl Physiol. 111(6):1575–1583.

20.

Lanir

Salant

Foux

. 1988. Physico-chemical and microstructural changes in collagen fiber bundles following stretch in-vitro. Biorheology. 25(4):591–603.

21.

Liu

Keikhosravi

Pehlke

Bredfeldt

Dutson

Liu

Mehta

Claus

Patel

Conklin

, et al. 2020. Fibrillar collagen quantification with curvelet transform based computational methods. Front Bioeng Biotechnol. 8:198.

22.

Mabuchi

Matsuzaka

Shimono

. 2002. Cell proliferation and cell death in periodontal ligaments during orthodontic tooth movement. J Periodontal Res. 37(2):118–124.

23.

Martino

Perestrelo

Vinarský

Pagliari

Forte

. 2018. Cellular mechanotransduction: from tension to function. Front Physiol. 9:824.

24.

Meikle

. 2006. The tissue, cellular, and molecular regulation of orthodontic tooth movement: 100 years after Carl Sandstedt. Eur J Orthod. 28(3):221–240.

25.

Meng

Han

Huang

Bai

Jing

. 2010. Orthodontic mechanical tension effects on the myofibroblast expression of alpha-smooth muscle actin. Angle Orthod. 80(5):912–918.

26.

Nanci

. 2012. Ten Cate’s oral histology. Development, structure, & function. Mosby.

27.

Pini

Zysset

Botsis

Contro

. 2004. Tensile and compressive behaviour of the bovine periodontal ligament. J Biomech. 37(1):111–119.

28.

Roguljic

Matthews

Yang

Cvija

Mina

Kalajzic

. 2013. In vivo identification of periodontal progenitor cells. J Dent Res. 92(8):709–715.

29.

Ruiz

Chen

. 2008. Emergence of patterned stem cell differentiation within multicellular structures. Stem Cells. 26(11):2921–2927.

30.

Somerman

Archer

Imm

Foster

. 1988. A comparative study of human periodontal ligament cells and gingival fibroblasts in vitro. J Dent Res. 67(1):66–70.

31.

Sun

Janjic Rankovic

Folwaczny

Otto

Wichelhaus

Baumert

. 2021. Effect of tension on human periodontal ligament cells: systematic review and network analysis. Front Bioeng Biotechnol. 9:695053.

32.

Van Driel

van Leeuwen

Von den Hoff

Maltha

Kuijpers-Jagtman

. 2000. Time-dependent mechanical behaviour of the periodontal ligament. Proc Inst Mech Eng H. 214(5):497–504.

33.

Wise

King

. 2008. Mechanisms of tooth eruption and orthodontic tooth movement. J Dent Res. 87(5):414–434.

34.

Yamamoto

Ugawa

Kawamura

Yamashiro

Kochi

Ideguchi

Takashiba

. 2018. Modulation of microenvironment for controlling the fate of periodontal ligament cells: the role of Rho/ROCK signaling and cytoskeletal dynamics. Cell Commun Signal. 12(1):369–378.

35.

Yang

Wang

Zhao

. 2015. In vitro mechanical loading models for periodontal ligament cells: from two-dimensional to three-dimensional models. Arch Oral Biol. 60(3):416–424.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

6.91 MB

Engineered 3D Periodontal Ligament Model with Magnetic Tensile Loading

Abstract

Keywords

Get full access to this article

References

Supplementary Material