. 2012 May;40(5):1102-10.

doi: 10.1007/s10439-011-0490-3. Epub 2011 Dec 20.

Collagen fiber re-alignment in a neonatal developmental mouse supraspinatus tendon model

Kristin S Miller¹, Brianne K Connizzo, Louis J Soslowsky

Affiliations

PMID: 22183194
PMCID: PMC3336024
DOI: 10.1007/s10439-011-0490-3

Collagen fiber re-alignment in a neonatal developmental mouse supraspinatus tendon model

Kristin S Miller et al. Ann Biomed Eng. 2012 May.

. 2012 May;40(5):1102-10.

doi: 10.1007/s10439-011-0490-3. Epub 2011 Dec 20.

Authors

Kristin S Miller¹, Brianne K Connizzo, Louis J Soslowsky

Affiliation

¹ McKay Orthopaedic Research Laboratory, University of Pennsylvania, Philadelphia, PA 19104-6081, USA.

PMID: 22183194
PMCID: PMC3336024
DOI: 10.1007/s10439-011-0490-3

Abstract

Collagen fiber re-alignment is one postulated mechanism of tendon structural response to load. While collagen fiber distribution has been shown to vary by tendon location in the supraspinatus tendon (SST), changes in local re-alignment behavior have not been examined throughout postnatal development. Postnatal tendons, with immature collagen fibrils, may respond to load in a much different manner than collagen fibers with mature fiber-fiber and fiber-matrix connections. Local collagen fiber re-alignment is quantified throughout tensile mechanical testing in a developmental mouse SST model and corresponding mechanical properties measured. Collagen fiber re-alignment occurred during preconditioning for 28 day old tendons, at the toe-region for 10 day tendons and at the linear-region for 4 day tendon midsubstance. Mechanical properties increased with developmental age. Linear modulus was lower at the insertion site compared to the midsubstance location at all time points. Local differences in collagen fiber distributions were found at 10 and 28 days for all mechanical testing points (except the 10 day transition point). This study found that collagen fiber re-alignment depends on developmental age and suggests that collagen fibrillogenesis may influence the tendon's ability to structurally respond to load. Additionally, results indicate that the insertion site and tendon midsubstance locations develop differently.

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Figures

**Figure 1**
Angled side-view of the tendon tensile testing setup showing polarized light and imaging system: light source, rotating cross-polarized sheets, stepper motors, and camera.

**Figure 2**
A representative load-displacement curve from each age group (4, 10 and 28 days) is shown demonstrating the decrease in transition strain between 28 and 10 day tendons.

**Figure 3**
Circular variance (VAR) values for representative samples demonstrate that re-alignment (decrease in VAR) occurred during preconditioning for 4 days (top) insertion site, at the linear-region for 4 day midsubstance, at the toe-region for both 10 day (middle) locations, and during preconditioning for both 28 day (bottom) locations. * = p<0. 025

**Figure 4**
A lower linear modulus is present at the insertion site compared to the midsubstance location at all time points. An increase in linear modulus is seen between 4 and 10 days at both locations.

**Figure 5**
Transition strain decreases with age at the insertion site and from 10 to 28 days at the midsubstance. A local decrease in transition strain from the insertion site to the midsubstance location was noted at 4 days.

See this image and copyright information in PMC

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Collagen fiber re-alignment in a neonatal developmental mouse supraspinatus tendon model

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Collagen fiber re-alignment in a neonatal developmental mouse supraspinatus tendon model

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