Properties of the Nasal Cartilage, from Development to Adulthood: A Scoping Review

Baddam, Pranidhi; Bayona-Rodriguez, Francy; Campbell, Sandra; El‐Hakim, Hamdy; Graf, Daniel

doi:10.1177/19476035221087696

Cited by 13 publications

(5 citation statements)

References 96 publications

(180 reference statements)

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“…The homogeneous distributions of both FCD and

along the depth generated constant strain values. The condition of a constant intrinsic modulus of the collagen network can be attained in neonatal cartilage [ 17 ] or nasal cartilage [ 42 , 43 ] with a uniform fibril organization where most fibers align parallel to an external surface, i.e.,

= 0. The inhomogeneous case of both FCD and

used the same parameters as those used to simulate the depth-dependent strain in Figure 4 .…”

Section: Resultsmentioning

confidence: 99%

Depth-Dependent Strain Model (1D) for Anisotropic Fibrils in Articular Cartilage

Batool,

Roth,

Xia

2024

Materials

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The mechanical response of articular cartilage (AC) under compression is anisotropic and depth-dependent. AC is osmotically active, and its intrinsic osmotic swelling pressure is balanced by its collagen fibril network. This mechanism requires the collagen fibers to be under a state of tensile pre-strain. A simple mathematical model is used to explain the depth-dependent strain calculations observed in articular cartilage under 1D axial compression (perpendicular to the articular surface). The collagen fibers are under pre-strain, influenced by proteoglycan concentration (fixed charged density, FCD) and collagen stiffness against swelling stress. The stiffness is introduced in our model as an anisotropic modulus that varies with fibril orientation through tissue depth. The collagen fibers are stiffer to stretching parallel to their length than perpendicular to it; when combined with depth-varying FCD, the model successfully predicts how tissue strains decrease with depth during compression. In summary, this model highlights that the mechanical properties of cartilage depend not only on proteoglycan concentration but also on the intrinsic properties of the pre-strained collagen network. These properties are essential for the proper functioning of articular cartilage.

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“…The homogeneous distributions of both FCD and

= 0. The inhomogeneous case of both FCD and

used the same parameters as those used to simulate the depth-dependent strain in Figure 4 .…”

Section: Resultsmentioning

confidence: 99%

Depth-Dependent Strain Model (1D) for Anisotropic Fibrils in Articular Cartilage

Batool,

Roth,

Xia

2024

Materials

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“…3 Although there are extensive studies on the structure of cartilage in the joints, little is known about the structure of collagen and the extracellular matrix (ECM) of facial and costal cartilages; our current understanding of morphologic cartilages, such as septal cartilage, predicates on inferences through other studies. 4 In this study, we examined septal, auricular, costal, and lower lateral (alar) cartilage specimens, the principal cartilages used in rhinoplasty and nasal reconstruction operations, using second harmonic generation microscopy to image type II collagen in the ECM. Additionally, the size and density of chondrocytes was measured, and collagen directionality was calculated.…”

Section: Introductionmentioning

confidence: 99%

“…Although there are extensive studies on the structure of cartilage in the joints, little is known about the structure of collagen and the extracellular matrix (ECM) of facial and costal cartilages; our current understanding of morphologic cartilages, such as septal cartilage, predicates on inferences through other studies 4 …”

Section: Introductionmentioning

confidence: 99%

Second Harmonic Imaging of Nasal, Auricular, and Costal Cartilage

et al. 2023

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ObjectiveThere is little knowledge about the histological organization of facial and costal cartilages in terms of matrix structure and cell morphology. Second harmonic generation (SHG) imaging is a nonlinear imaging technique that capitalizes on signal generation from highly ordered macromolecules such as collagen fibers. The purpose of this study was to use SHG microscopy to image collagen extracellular matrix (ECM) structure, chondrocyte size, and density of these cartilages.Study DesignExperimental.MethodsSurgical remnants of septal, lower lateral, rib, and auricular cartilages were collected following surgery, sectioned into 0.5–1 mm thick samples and fixed to facilitate batch process imaging. A Leica TCS SP8 MP Microscope and multiphoton laser were used to image the specimens. Images were analyzed for cell size, cell density, and collagen fiber directionality patterns using ImageJ.ResultsSHG images of septal specimens show mesh‐like structure of the ECM. There appears to be a superficial layer, characterized by flattened lacunae and middle zone, marked by circular lacunae clusters, similar to what is observed in articular cartilage. The structure of the ECM depicts a visible orientation perpendicular to the surface of the perichondrium. Cell size and density analysis through ImageJ suggests variety across cartilage types. Directionality analysis indicates that the collagen in the ECM displays preferred direction.ConclusionThis study establishes clear extracellular models of facial and costal cartilages. Limitations include heterogeneous cartilage thickness due to processing difficulties. Further studies include automating the cutting process to increase uniformity of tissue thickness and increasing sample size to further validate results.Level of EvidenceII Laryngoscope, 2023

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“…Among them, TSDO applies force to the growing cranial suture and facial suture and induces the formation of new bone around the suture, which changes the shape and position of craniomaxillofacial bone, with the advantages of less trauma and fewer complications 11 . It is worth noting that the nasal septal cartilage is sensitive to the traction force, and the 3-dimensional growth of the midfacial bone can remove the space restriction on the nasal septal growth, which promotes the growth of the nasal septal cartilage 12 . Previous studies mainly focused on the effect of TSDO on the 3-dimensional growth of maxilla, while there was no report on the effect of TSDO on the nasal bone, nasal septum, and nasal airway.…”

mentioning

confidence: 99%

“… 11 It is worth noting that the nasal septal cartilage is sensitive to the traction force, and the 3-dimensional growth of the midfacial bone can remove the space restriction on the nasal septal growth, which promotes the growth of the nasal septal cartilage. 12 Previous studies mainly focused on the effect of TSDO on the 3-dimensional growth of maxilla, while there was no report on the effect of TSDO on the nasal bone, nasal septum, and nasal airway.…”

mentioning

confidence: 99%

The Effect of Trans-Sutural Distraction Osteogenesis on Nasal Bone, Nasal Septum, and Nasal Airway in the Treatment for Midfacial Hypoplasia in Growing Patients

Bao

Jin

Bai

et al. 2023

Journal of Craniofacial Surgery

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The purposes of this study were to analyze the effect of trans-sutural distraction osteogenesis (TSDO) on nasal bone, nasal septum, and nasal airway in the treatment of midfacial hypoplasia. A total of 29 growing patients with midfacial hypoplasia who underwent TSDO by a single surgeon were enrolled. The 3-dimensional measurement of nasal bone and nasal septum changes was performed using computed tomography (CT) images obtained preoperatively (T0) and postoperatively (T1). One patient was selected to establish 3-dimensional finite element models to simulate the characteristics of nasal airflow field before and after traction. After traction, the nasal bone moved forward significantly (P < 0.01). The septal deviation angle was lower than that before traction (14.43 ± 4.70 versus 16.86 ± 4.59 degrees) (P < 0.01). The length of the anterior and posterior margin of the vomer increased by 21.4% (P < 0.01) and 27.6% (P < 0.01), respectively, after TSDO. The length of the posterior margin of the perpendicular plate of ethmoid increased (P < 0.05). The length of the posterior inferior and the posterior superior margin of the nasal septum cartilage increased (P < 0.01) after traction. The cross-sectional area of nasal airway on the deviated side of nasal septum increased by 23.0% after traction (P < 0.05). The analysis of nasal airflow field showed that the pressure and velocity of nasal airflow and the nasal resistance decreased. In conclusion, TSDO can promote the growth of the midface, especially nasal septum, and increase the nasal space. Furthermore, TSDO is conductive to improve nasal septum deviation and decrease nasal airway resistance.

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Properties of the Nasal Cartilage, from Development to Adulthood: A Scoping Review

Cited by 13 publications

References 96 publications

Depth-Dependent Strain Model (1D) for Anisotropic Fibrils in Articular Cartilage

Depth-Dependent Strain Model (1D) for Anisotropic Fibrils in Articular Cartilage

Second Harmonic Imaging of Nasal, Auricular, and Costal Cartilage

The Effect of Trans-Sutural Distraction Osteogenesis on Nasal Bone, Nasal Septum, and Nasal Airway in the Treatment for Midfacial Hypoplasia in Growing Patients

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