ABSTRACT: Cyclic stretching and growth factors like TGF-? have been used to enhance extracellular matrix (ECM) production by cells in engineered tissue to achieve requisite mechanical properties. In this study, the effects of TGF-?1 were evaluated during long-term cyclic stretching of fibrin-based tubular constructs seeded with neonatal human dermal fibroblasts. Samples were evaluated at 2, 5, and 7 weeks for tensile mechanical properties and ECM deposition. At 2 weeks, +TGF-?1 samples had 101% higher collagen concentration but no difference in ultimate tensile strength (UTS) or modulus compared to -TGF-?1 samples. However, at weeks 5 and 7, -TGF-?1 samples had higher UTS/modulus and collagen concentration, but lower elastin concentration compared to +TGF-?1 samples. The collagen was better organized in -TGF-?1 samples based on picrosirius red staining. Western blot analysis at weeks 5 and 7 showed increased phosphorylation of ERK in -TGF-?1 samples, which correlated with higher collagen deposition. The TGF-?1 effects were further evaluated by western blot for ?SMA and SMAD2/3 expression, which were 16-fold and 10-fold higher in +TGF-?1 samples, respectively. The role of TGF-?1 activated p38 in inhibiting phosphorylation of ERK was evaluated by treating samples with SB203580, an inhibitor of p38 activation. SB203580-treated cells showed increased phosphorylation of ERK after 1 hour of stretching and increased collagen production after 1 week of stretching, demonstrating an inhibitory role of activated p38 via TGF-?1 signaling during cyclic stretching. One advantage of TGF-?1 treatment was the 4-fold higher elastin deposition in samples at 7 weeks. Further cyclic stretching experiments were thus conducted with constructs cultured for 5 weeks without TGF-?1 to obtain improved tensile properties followed by TGF-?1 supplementation for 2 weeks to obtain increased elastin content, which correlated with a reduction in loss of pre-stress during preconditioning for tensile testing, indicating functional elastin. This study shows that a sequential stimulus approach - cyclic stretching with delayed TGF-?1 supplementation - can be used to engineer tissue with desirable tensile and elastic properties.