Translating in vitro models into pre-clinical development is a significant hurdle in the advancement of tissue-engineered therapies. Potential therapies are typically developed in vitro, and then must be vetted in a relevant animal model before beginning human clinical trials. For tissue-engineered organ replacements, this means developing a species-specific implant. Construct design for preclinical animal trials may differ from both the initial in vitro product and the eventual human implant.

For example, tissue engineering of a vocal fold replacement is an exciting potential treatment for vocal fold scars that impair vibration and cause voice disturbance. Few reliable options currently exist to improve the dysphonia1234. This laboratory has developed a cell-populated three-dimensional tissue-engineered construct intended for vocal fold cover layer replacement5. Human adipose-derived stem cells (ASC) embedded within a clotted cryoprecipitate scaffold differentiate into a bilayered construct intended for vocal fold cover replacement5. This model shows promising function in vitro as a replacement for the vibratory lamina propria and epithelial layers6. An advantage of the design is its composition from all potentially autologous sources. While this model is appealing for human use, it requires adaptation for pre-clinical studies in animals. The vocal folds are exquisitely sensitive to scar formation, and the immune response expected from the xenograft implant of human cells or scaffold may significantly confound their wound healing.

In this work, we set out to develop a tissue-engineered construct suitable for implantation in rabbit vocal folds. Rabbits are a favorable animal model for study of the larynx due to adequate laryngeal size for implantation surgery, histologic similarities to human larynges, and economical animal husbandry relative to larger mammals7. They can undergo phonation both in vivo and in excised larynx preparations89. Furthermore, ASC are easily harvested from rabbits as well as humans. Here we report the production of a tissue-engineered mucosa replacement from rabbit ASC that will allow for pre-clinical construct implantation studies. Key differences in the in vitro development between the human and rabbit cell models are highlighted.

Tissue engineering and regenerative medicine hold promise for diseases that are currently difficult to treat because of lack of suitable therapies or self-repair mechanisms. Vocal fold scarring is an excellent example. The specialized extracellular matrix of the vocal fold lamina propria and its attached epithelium are, thus far, irreplaceable after injury. Its geometry also makes the vocal fold mucosa a good candidate for tissue engineering in the laboratory. It is a small, thin structure with low metabolic activity due to sparse cellularity; these factors ensure adequate nutritional perfusion without need for neovascularization.

Befitting the label “stem cells”, adipose-derived stem cells possess the capabilities of self-renewal and multiple differentiation potential11. ASC may be more clinically applicable than other stem cell types because they are quite easily harvested from adult liposuction material and are simple to maintain in culture12. As such, ASC have been proposed as a cell source for engineering and repair of nearly any conceivable tissue type1314. They are currently being investigated in nearly one hundred active human clinical trials, primarily of cell injections alone without scaffolds15. Of particular interest are the immune modulating and wound healing properties of these cells16 Development of more complex three-dimensional tissue and organ replacement is still in the in vitro and pre-clinical animal implantation phases.

We focused our attention here on rabbit ASC, since rabbits are an ideal small animal model for studies of the larynx. The larynx is accessible, adequately sized, able to phonate in an excised setting; and histologically and structurally similar to the human larynx. Furthermore, the inherently silent behavior of rabbits minimizes disruption to the healing implant. Multi-potent rabbit ASC are capable of differentiating into bone and fat-like lineages, as demonstrated here and in prior studies17. Rabbit ASC have been shown to differentiate into an epithelial phenotype when exposed to an air liquid interface and a growth factor cocktail, consisting of all-trans retinoic acid, EGF, and further enhanced by hepatocyte growth factor and keratinocyte growth factor for 12 days18. That study was not performed in a three-dimensional scaffold.

Fibrin was chosen as the biological scaffold for this study due to its importance in normal wound healing, its biodegradable nature, and its potential for autologous sourcing from plasma. As the principal proteinaceous component of blood clots, fibrin is formed when the enzyme thrombin cleaves end-terminal peptides from circulating fibrinogen protein. Exposing the fibrinogen terminals allows rapid self-polymerization, and long fibrin chains result. Initial attempts at embedding the rabbit ASC used human cryoprecipitate as fibrinogen source, as was previously used for human ASC5. However, unlike human ASC, the rabbit ASC rapidly degraded and compacted the cryoprecitate-based fibrin; constructs were largely degenerated within seven days. Thus a commercial purified fibrinogen isolated from rabbit plasma was utilized, and this created durable constructs that were handled beyond 21 days without difficulty or breakdown. Potential explanations for this difference are hypothesized. Cryoprecipitate is an unpurified source of clotting factors from plasma, which does include other bound proteins such as matrix metalloproteinases that could degrade the scaffold. It is also possible that human antigens from the cryoprecipitate activated the rabbit ASC to secrete degradatory enzymes. With either hypothesis, the net balance of proteinases to inhibitors likely differed between the human and rabbit cell cultures. Also, fibrinogen concentration within the cryoprecipitate was unknown and likely differed from that used in the pure form. Finally, some of the volume loss appeared due to greater cell-mediated contraction in the cryoprecipitate case, either due to stronger cell adhesion or a more contractile state. Regardless of the cause, the excess scaffold loss with human cryoprecipitate highlights the importance of designing each component of an implant for the intended species and target tissue. The less contractile case with rabbit fibrinogen is better suited to implant in the vocal fold where preventing repeat scar formation is paramount. Also, avoiding human antigens in the rabbit implant will reduce the risk of immune rejection. Similarly, rabbit fibrinogen was preferred over the more readily available bovine fibrinogen, to avoid undue antigen exposure during ultimate implantation in rabbit vocal folds.

For eventual human implantation, a fibrin scaffold could be produced from either autologous cryoprecipitate or pooled human donor cryoprecipitate. The risk of viral transmission or inflammatory reaction from allogeneic human cryoprecipitate implantation in the solid form is not well delineated, but is likely to be low since human pooled fibrin and thrombin-based products have been safely used for surgical hemostasis for many years19. Interestingly, even the use of bovine aprotinin components only very rarely leads to a clinical immunologic response in humans20. Regardless, a clear advantage of fibrin as a scaffold is that it can be prepared from human plasma for autologous re-implantation without risk. This would be feasible in rabbit implant studies as well, but would significantly increase the complexity of an experimental series by requiring pre-implantation plasma collection and animal-specific culture.

We did investigate epithelial differentiation in this system, but found that all cells primarily maintained a mesenchymal phenotype. Unwanted mesenchymal differentiation to produce lipid or mineral deposits did not occur. Li et al demonstrated differentiation of rabbit ASC to epithelial-like cells in a monolayer air liquid interface system, with nearly 70% epithelial-like differentiation17. They used a thin collagen type IV coated membrane with a variety of growth factors to induce high levels of cytokeratin 19 (an early epithelial marker) staining and low levels of cytokeratin 13 (a mucosal epithelial marker). In our system using EGF treatment in a fibrin gel, as was previously used with human ASC, clear expression of the epithelial marker CK19 was not evident after two weeks in culture. This difference between human and rabbit cell behavior again highlights the importance of species-specific investigation.

The construct developed here, even without significant epithelial differentiation, is suitable for implantation as a vocal fold mucosa graft in rabbits. The in vivo microenvironment may direct differentiation of the superficial layer of cells to an epithelial phenotype. ASC or bone marrow derived stem cell injections into animal vocal folds in vivo decrease scaring and dense collagen deposition; improve viscoelasticity and mobility; and increase elastin production, vocal fold smoothness and collagen organization921222324. Furthermore, adding a micronized acellular dermal matrix or hydrogel scaffold to the injection decreased scarring925. The wound healing properties of ASC may be adequate to prevent scar formation after implantation, while the fibrin scaffold may further support ASC survival and differentiation. These aspects will be tested in a rabbit implantation trial.

Rabbit adipose-derived stem cells were used to create a three-dimensional tissue-engineered construct suitable for vocal fold cover replacement. The construct resembled the vocal fold lamina propria and epithelium in microstructure although not in cell phenotype. The construct was able to withstand handling and suturing similar to a native rabbit vocal fold cover layer. Notable differences were found in cell differentiation and scaffold degradation between human and rabbit ASC. This construct will be used for future in vivo implantation studies in rabbits.