OBJECTIVE: It was hypothesized that controlled, scaffold removal in engineered cartilage constructs would improve their collagen content and mechanical properties over time in culture. DESIGN: Preliminary experiments characterized the effects of agarase on cell-free agarose disks and cartilage explants. Immature bovine chondrocytes were encapsulated in agarose, cultured to day 42, and incubated with 100 units/mL agarase for 48 h. After treatment, constructs were cultured to day 91. The compressive Young's modulus and dynamic modulus of the constructs were determined every 2 weeks and immediately after agarase treatment. Post-mechanical testing, constructs were processed for biochemistry and histology. RESULTS: Agarase treatment on explants had no detrimental effect on the cartilage matrix. Treatment applied to engineered constructs on day 42 did not affect DNA or collagen content. Agarase treatment decreased tissue GAG content (via GAG loss to the media) and Young's modulus, both of which recovered to control values over time in culture. By day 91 agarase-treated constructs possessed approximately 25% more DNA, approximately 60% more collagen, and approximately 40% higher dynamic modulus compared to untreated controls. CONCLUSIONS: Scaffold degradation increased construct collagen content and dynamic mechanical properties, affirming the experimental hypothesis. The mechanism may lie in increased nutrient transport, increased space for collagen fibril formation, and cellular response to the loss of GAG with agarase treatment. The results highlight the role of the scaffold in retaining synthesized matrix during early and late tissue formation. This work also shows promise in developing an engineered tissue that may be completely free of scaffold material for clinical implantation.
OBJECTIVE: It was hypothesized that controlled, scaffold removal in engineered cartilage constructs would improve their collagen content and mechanical properties over time in culture. DESIGN: Preliminary experiments characterized the effects of agarase on cell-free agarose disks and cartilage explants. Immature bovine chondrocytes were encapsulated in agarose, cultured to day 42, and incubated with 100 units/mL agarase for 48 h. After treatment, constructs were cultured to day 91. The compressive Young's modulus and dynamic modulus of the constructs were determined every 2 weeks and immediately after agarase treatment. Post-mechanical testing, constructs were processed for biochemistry and histology. RESULTS: Agarase treatment on explants had no detrimental effect on the cartilage matrix. Treatment applied to engineered constructs on day 42 did not affect DNA or collagen content. Agarase treatment decreased tissue GAG content (via GAG loss to the media) and Young's modulus, both of which recovered to control values over time in culture. By day 91 agarase-treated constructs possessed approximately 25% more DNA, approximately 60% more collagen, and approximately 40% higher dynamic modulus compared to untreated controls. CONCLUSIONS: Scaffold degradation increased construct collagen content and dynamic mechanical properties, affirming the experimental hypothesis. The mechanism may lie in increased nutrient transport, increased space for collagen fibril formation, and cellular response to the loss of GAG with agarase treatment. The results highlight the role of the scaffold in retaining synthesized matrix during early and late tissue formation. This work also shows promise in developing an engineered tissue that may be completely free of scaffold material for clinical implantation.
Authors: R L Mauck; M A Soltz; C C Wang; D D Wong; P H Chao; W B Valhmu; C T Hung; G A Ateshian Journal: J Biomech Eng Date: 2000-06 Impact factor: 2.097
Authors: Alexander D Cigan; Brendan L Roach; Robert J Nims; Andrea R Tan; Michael B Albro; Aaron M Stoker; James L Cook; Gordana Vunjak-Novakovic; Clark T Hung; Gerard A Ateshian Journal: J Biomech Date: 2016-05-10 Impact factor: 2.712
Authors: Alexander D Cigan; Krista M Durney; Robert J Nims; Gordana Vunjak-Novakovic; Clark T Hung; Gerard A Ateshian Journal: Tissue Eng Part A Date: 2016-08-23 Impact factor: 3.845
Authors: Grace D O'Connell; Eric G Lima; Liming Bian; Nadeen O Chahine; Michael B Albro; James L Cook; Gerard A Ateshian; Clark T Hung Journal: J Knee Surg Date: 2012-07 Impact factor: 2.757
Authors: Grace D O'Connell; Jason V Fong; Neil Dunleavy; Avrum Joffe; Gerard A Ateshian; Clark T Hung Journal: J Orthop Res Date: 2012-06-15 Impact factor: 3.494
Authors: Alexander D Cigan; Robert J Nims; Michael B Albro; John D Esau; Marissa P Dreyer; Gordana Vunjak-Novakovic; Clark T Hung; Gerard A Ateshian Journal: Tissue Eng Part A Date: 2013-05-30 Impact factor: 3.845
Authors: Alexander D Cigan; Robert J Nims; Michael B Albro; Gordana Vunjak-Novakovic; Clark T Hung; Gerard A Ateshian Journal: J Biomech Date: 2014-10-23 Impact factor: 2.712