Ultrastructure and tensile properties of human tracheal cartilage.

The cartilage of the walls of the trachea and bronchi acts to keep these airways open despite intrathoracic pressure differences during breathing that would otherwise collapse them and limit air flow. Changes in biomechanical properties and composition of airway cartilage may contribute to altered lung function in obstructive lung diseases. To investigate the relationship between collagen organization and equilibrium tensile modulus within the structure of airway cartilage, we used scanning electron microscopy (SEM), histochemistry and equilibrium tensile testing to analyze tracheal cartilage from 10 humans aged 17-81 yr. We show that the surfaces of tracheal cartilage matrix are collagen-rich and surround a proteoglycan-rich core. Collagen fibrils in the superficial zones are oriented in the plane of the cartilage surface. In deeper layers of the cartilage, collagen fibrils are oriented less regularly. Equilibrium tensile modulus of 100 microm thick strips of cartilage was measured and was found to decrease with depth; from 13.6 +/- 1.5 MPa for the ablumenal superficial zone to 4.6 +/- 1.7 MPa in the middle zone (means +/- S.D., n = 10, p < 0.001). Stress-strain curves were linear for strains up to 10% with minimal residual strain. This is consistent with a model in which collagen fibres in the outer layers of the cartilage resist tensile forces, and hydrated proteoglycans in the central zone resist compression forces as the cartilage crescent bends.

Mechanical properties of human tracheal cartilage.

Biomechanical changes in airway cartilage could influence the mechanics of maximal expiratory flow and cough and the degree of shortening of activated airway smooth muscle. We examined the tensile stiffness of small samples of human tracheal cartilage rings in specimens obtained at autopsy from 10 individuals who ranged in age from 17 to 81 yr. The tensile properties of the cartilage were compared with its content of water (%water), glycosaminoglycans (chondroitin sulfate equivalents, mg/mg dry wt), and hydroxyproline content (mg hydroxyproline/mg dry weight). The average values for tensile stiffness ranged between 1 and 15 MPa and increased significantly with increasing age [tensile stiffness = 0.19 x (age in yr) + 2.02; r = 0.83, P less than 0.05]. The outermost layer of cartilage was the most stiff in all individuals, and the deeper layers were progressively less stiff. Water content and hydroxyproline content both decreased with increasing age. Thus tensile stiffness correlated inversely with water content and hydroxyproline content [tensile stiffness = -0.83 x (%water) + 16.4; r = 0.82, P less than .05 and tensile stiffness = -342 x (hydroxyproline content) + 25; r = 0.87, P less than 0.05]. Total tissue content of glycosaminoglycans did not change with age, although changes in glycosaminoglycan type and proteoglycan structure with increasing age have been described. We conclude that there are age-related changes in the biomechanical properties and biochemical composition of airway cartilage that could influence airway dynamics.