Cellular therapies play an important role in tendon tissue engineering with tenocytes being described as the most prominent cell population if available in large numbers. However, in vitro expansion of tenocytes in standard culture leads to phenotypic drift and cellular senescence. Recent work suggests that maintenance of tenogenic phenotype in vitro can be achieved by recapitulating different aspects of the native tendon microenvironment. One approach used to modulate the in vitro microenvironment and enhance extracellular matrix (ECM) deposition is macromolecular crowding (MMC). MMC is based on the addition of inert macromolecules to the culture media mimicking the dense extracellular matrix. In addition, as tendon has been described to be a relatively avascular and hypoxic tissue and low oxygen tension can stimulate collagen synthesis and cross-linking, we venture to assess the synergistic effect of MMC and low oxygen tension on human tenocyte phenotype maintenance by enhancing synthesis and deposition of tissue-specific ECM.

Human tendons were kindly provided from University Hospital Galway, after obtaining appropriate licenses, ethical approvals and patient consent. Afterwards, tenocytes were extracted using the migration method. Experiments were conducted at passage three. Optimization of MMC conditions was assessed using 50 to 500 μg/ml carrageenan (Sigma Aldrich, UK). For variable oxygen tension cultures, tenocytes were incubated in a Coy Lab (USA) hypoxia chamber. ECM synthesis and deposition were assessed using SDS-PAGE (BioRad, UK) and immunocytochemistry (ABCAM, UK) analysis. Protein analysis for Scleraxis (ABCAM, UK) was performed using western blot. Gene analysis was conducted using a gene array (Roche, Ireland). Cell morphology was assessed using bright-field microscopy. All experiments were performed at least in triplicate. MINITAB (version 16, Minitab, Inc.) was used for statistical analysis. Two-sample t-test for pairwise comparisons and ANOVA for multiple comparisons were conducted

SDS-PAGE and immunocytochemistry analysis demonstrated that human tenocytes treated with the optimal MMC concentration at 2% oxygen tension showed increased synthesis and deposition of collagen type I, the major component of tendon ECM. Moreover, immunocytochemistry for the tendon-specific ECM proteins collagen type III, V, VI and fibronectin illustrated enhanced deposition when cells were treated with MMC at 2% oxygen tension. In addition, protein analysis revealed elevated dexpression of the tendon-specific protein Sclearaxis, while a detailed gene analysis revealed upregulation of tendon-related genes and downregulation of trans-differentiation markers again when cells cultured with MMC at 2% oxygen tension. Finally, low oxygen tension and MMC did not affect the metabolic activity, proliferation and viability of human tenocytes.

Collectively, results suggest that the synergistic effect of MMC and low oxygen tension can accelerate the formation of ECM-rich substitutes, which stimulates tenogenic phenotype maintenance. Currently, the addition of substrate aligned topography together with MMC and hypoxia is being investigated in this multifactorial study for the development of an implantable device for tendon regeneration.

Cellular therapies play an important role in tendon tissue engineering with tenocytes being described as the most prominent cell population if available in large numbers. In vitro expansion of tenocytes in standard culture leads to phenotypic drift and cellular senescence. Maintenance of tenogenic phenotype in vitro can be achieved by recapitulating different aspects of the tendon microenvironment. One approach used to modulate in vitro microenvironment and enhance extracellular matrix (ECM) deposition is macromolecular crowding (MMC). In addition, as tendon has been described to be a relatively avascular and hypoxic tissue and low oxygen tension can stimulate collagen synthesis and cross-linking through the activation of hypoxia-inducible factor 1-alpha (HIF1-α), we venture to assess the synergistic effect of MMC and low oxygen tension on human tenocyte phenotype maintenance. SDS-PAGE and immunocytochemistry analysis demonstrated that human tenocytes treated with MMC at 2 % oxygen tension showed increased synthesis and deposition of collagen type I. Moreover, immunocytochemistry for the tendon-specific ECM proteins collagen type III, V, VI and fibronectin illustrated enhanced deposition when cells were treated with MMC at 2 % oxygen tension. In addition, western blot analysis revealed increased expression of tendon-specific protein Scleraxis, while a detailed gene analysis illustrated upregulation of tendon-specific genes and downregulation of trans-differentiation genes again when cells cultured with MMC under hypoxic conditions. Collectively, results suggest that the synergistic effect of MMC and low oxygen tension can accelerate the formation of ECM-rich substitutes, which stimulates tenogenic phenotype maintenance.

Cellular therapies play an important role in tendon tissue engineering and regenerative medicine with tenocytes being described as the most prominent cell population for these applications if available in large numbers. However, this is difficult to achieve, because in vitro expansion of tenocytes leads to phenotypic drift and loss of function. Recent work suggests that maintenance of tenogenic phenotype in vitro can be achieved by recapitulating different aspects of the native tendon microenvironment. One approach used to modulate in vitro microenvironment and enhance extracellular matrix (ECM) deposition is macromolecular crowding (MMC). MMC is based on the addition of inert macromolecules to the culture media to mimic the dense extracellular matrix and accelerate the production of ECM-rich substitutes. In addition, as tendon has been described to be a relatively avascular and hypoxic tissue and low oxygen tension can stimulate collagen synthesis and cross-linking through the activation of hypoxia-inducible factor 1-alpha (HIF1-α), we venture to assess the synergistic effect of MMC and low oxygen tension on human tenocyte phenotype maintenance by enhancing deposition of tissue-specific extracellular matrix.

SDS-PAGE and immunocytochemistry analysis, demonstrated that human tenocytes treated with the optimal MMC concentration at 2% oxygen tension showed increased collagen type I synthesis and deposition after 7 days. Moreover, immunocytochemistry for collagen type III, type V, VI, elastin and fibronectin illustrated enhanced deposition when cells were treated with MMC at 2% oxygen tension. In addition, it was shown that low oxygen tension and MMC did not affect the spindle-shape morphology, metabolic activity, proliferation and viability of human tenocytes Collectively, these results suggest that the synergistic effect of optimal macromolecular crowding concentration and low oxygen tension (2%) can accelerate the formation of ECM-rich substitutes, which may stimulate tenogenic phenotype maintenance. Further gene and protein analysis for tendon specific markers should be performed to validate our promising results.