While many tissue-engineered constructs aim to treat cartilage defects, most involve chondrocyte or stem cell seeding on scaffolds. The clinical application of cell-based techniques is limited due to the cost of maintaining cellular constructs on the shelf, potential immune response to allogeneic cell lines, and autologous chondrocyte sources requiring biopsy from already diseased or injured, scarce tissue. An acellular scaffold that can induce endogenous influx and homogeneous distribution of native stem cells from bone marrow holds great promise for cartilage regeneration. This study aims to develop such an acellular scaffold using designed, channeled architecture that simultaneously models the native zones of articular cartilage and subchondral bone. Highly porous, hydrophilic chitosan-alginate (Ch-Al) scaffolds were fabricated in three-dimensionally printed (3DP) molds designed to create millimeter scale macro-channels. Different polymer preform casting techniques were employed to produce scaffolds from both negative and positive 3DP molds. Macro-channeled scaffolds improved cell suspension distribution and uptake overly randomly porous scaffolds, with a wicking volumetric flow rate of 445.6 ± 30.3 mm(3) s(-1) for aqueous solutions and 177 ± 16 mm(3) s(-1) for blood. Additionally, directional freezing was applied to Ch-Al scaffolds, resulting in lamellar pores measuring 300 μm and 50 μm on the long and short axes, thus creating micrometer scale micro-channels. After directionally freezing Ch-Al solution cast in 3DP molds, the combined macro- and micro-channeled scaffold architecture enhanced cell suspension uptake beyond either macro- or micro-channels alone, reaching a volumetric flow rate of 1782.1 ± 48 mm(3) s(-1) for aqueous solutions and 440.9 ± 0.5 mm(3) s(-1) for blood. By combining 3DP and directional freezing, we can control the micro- and macro-architecture of Ch-Al to drastically improve cell influx into and distribution within the scaffold, while achieving porous zones that mimic articular cartilage zonal architecture. In future applications, precisely controlled micro- and macro-channels have the potential to assist immediate endogenous bone marrow uptake, stimulate chondrogenesis, and encourage vascularization of bone in an osteochondral scaffold.
The beautifully orchestrated complexity of the temporal spatial growth factor gradients during embryogenesis offer a striking contrast to systemic bolus administration that lack tissue specificity and sustained protein localization, often requiring supraphysiological protein doses to produce the desired therapeutic dose. These attributes may be responsible for clinically observed dangerous tissue overgrowth, inflammation, and even tumor formation. Growth factor delivery within an implanted scaffold is a very attractive way to modulate cell behavior. For short term delivery, proteins can be non-specifically adsorbed to the material surface or simply entrapped within the bulk scaffold. For more sustained delivery, many researchers have turned to the ever increasing list of covalent immobilization methods that have profound applications in purification, biosensing, imaging, and drug discovery by tethering proteins, nucleic acids, carbohydrates, synthetic polymers, small molecules, nanotubes, and even whole cells. This review focuses on the use of covalent immobilization to achieve sustained growth factor delivery for tissue engineering. Covalent immobilization techniques will be reviewed in terms of design, protein bioactivity/stability, efficiency, and spatiotemporal distribution. Further, the biological response to sustained growth factor delivery will also be covered, such as cell interaction, cell responsiveness, proliferation, differentiation, extracellular matrix production, and tissue regeneration. This focused review is anticipated to inform investigators on the selection of optimal immobilization strategies for their specific applications.
Chitosan-alginate (Ch-Al) natural polysaccharide blends have been used for wound healing, tissue engineering, and drug delivery due to their ability to form pH-dependent ionic chain-chain interactions. Yet, the biomechanical properties and growth factor (GF) release kinetics of Ch-Al, which are important in controlling the microenvironment during tissue regeneration, have not been fully explored. This study examines the compressive elastic modulus of many Ch-Al scaffold formulations and crosslinking conditions, and also the strain recovery after compressive deformation of Ch-Al scaffolds, both of which make Ch-Al an attractive composite for reproducing articular cartilage's resistance to and resiliency under compression. Cell viability, proliferation, and in vitro cartilaginous matrix production (collagen type II, glycosaminoglycans, aggrecan) without supplemental GFs are also investigated, demonstrating the polymer blend's inherent chondrogenic properties. Additionally, this study explores the ability of Ch-Al chain functional groups to control and extend GF delivery and minimize GF burst release, using model proteins BSA and histone at high loading dose and chondrogenic protein TGF-β1 at low loading dose in complete media. Expedited cartilaginous matrix synthesis on Ch-Al with low dose TGF-β1 release is evaluated, with Ch-Al supporting homogeneous matrix deposition and lacunae formation as early as 3 weeks due to Ch-Al's maintenance of GF bioactivity and sustained GF delivery. These results illustrate the potential to focus the formulational range of Ch-Al to provide enhanced mechanical performance and controlled, bioactive GF release to cooperatively promote cartilage regeneration. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 272-282, 2017.
3D digital microscopy was used to develop a rapid alternative approach to quantify the effects of specific laser parameters on soft tissue ablation and charring in vitro without the use of conventional tissue processing techniques. Two diode lasers operating at 810 and 980 nm wavelengths were used to ablate three tissue types (bovine liver, turkey breast, and bovine muscle) at varying laser power (0.3, 1.0, and 2.0 W) and velocities (1-50 mm/s). Spectrophotometric analyses were performed on each tissue to determine tissue-specific absorption coefficients and were considered in creating wavelength-dependent energy attenuation models to evaluate minimum heat of tissue ablations. 3D surface contour profiles characterizing tissue damage revealed that ablation depth and tissue charring increased with laser power and decreased with lateral velocity independent of wavelength and tissue type. While bovine liver ablation and charring were statistically higher at 810 than 980 nm (p < 0.05), turkey breast and bovine muscle ablated and charred more at 980 than 810 nm (p < 0.05). Spectrophotometric analysis revealed that bovine liver tissue had a greater tissue-specific absorption coefficient at 810 than 980 nm, while turkey breast and bovine muscle had a larger absorption coefficient at 980 nm (p < 0.05). This rapid 3D microscopic analysis of robot-driven laser ablation yielded highly reproducible data that supported well-defined trends related to laser-tissue interactions and enabled high throughput characterization of many laser-tissue permutations. Since 3D microscopy quantifies entire lesions without altering the tissue specimens, conventional and immunohistologic techniques can be used, if desired, to further interrogate specific sections of the digitized lesions.
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