Rapid Prototyping of Flexible Structures for Tissue Engineered Ear Reconstruction

The tissue engineered ear has been an iconic symbol of the field since 1991, when the report of an engineered ear in a mouse model was first published A tissue engineered ear has an inherent advantage over conventional approaches because the structure is derived from the patient's own cartilage. In this approach, autologous auricular chondrocytes are harvested from the patient and grown within an ear-shaped scaffold. However, as the scaffold degrades or remodels, the ear-shaped structure undergoes significant distortion, resulting in a skewed ear shape that is smaller and often unrecognizable In order to maintain the desired ear geometry, a composite scaffold concept was developed Methods Several functional requirements for the manufacturing process were identified. First, the wire framework must be created with arbitrary three dimensional (3D) control, and with a diameter significantly smaller than the thickness of normal ear cartilage, which is about 2 mm. The bending stiffness must be sufficiently high so that shape is maintained during neocartilage maturation and sufficiently low such that flexibility of the overall structure is not impaired. The material must be approved for clinical use, and must not cause an inflammatory reaction. Finally, the manufacturing process must be capable of producing single, custom parts without significant cost burden. Plastic surgeons identified titanium and stainless steel as preferred materials due to their long history of success in medical implants Three manufacturing processes were identified that are capable of producing arbitrary shapes with the listed metals: wire bending, direct metal laser sintering (DMLS) Results Ear frameworks produced using DMLS and EBM technology are shown in Interpretation Ear frameworks produced using DMLS and EBM technology are shown i

The Rise and Fall of the Adaptive Landscape?

The discussion of the adaptive landscape in the philosophical literature appears to be divided along the following lines. On the one hand, some claim that the adaptive landscape is either “uninterpretable” or incoherent. On the other hand, some argue that the adaptive landscape has been an important heuristic, or tool in the service of explaining, as well as proposing and testing hypotheses about evolutionary change. This paper attempts to reconcile these two views

Extensively Expanded Auricular Chondrocytes Form Neocartilage In Vivo

Objective: Our goal was to engineer cartilage in vivo using auricular chondrocytes that underwent clinically relevant expansion and using methodologies that could be easily translated into health care practice. Design: Sheep and human chondrocytes were isolated from auricular cartilage biopsies and expanded in vitro. To reverse dedifferentiation, expanded cells were either mixed with cryopreserved P0 chondrocytes at the time of seeding onto porous collagen scaffolds or proliferated with basic fibroblast growth factor (bFGF). After 2-week in vitro incubation, seeded scaffolds were implanted subcutaneously in nude mice for 6 weeks. The neocartilage quality was evaluated histologically; DNA and glycosaminoglycans were quantified. Cell proliferation rates and collagen gene expression profiles were assessed. Results: Clinically sufficient over 500-fold chondrocyte expansion was achieved at passage 3 (P3); cell dedifferentiation was confirmed by the simultaneous COL1A1/3A1 gene upregulation and COL2A1 downregulation. The chondrogenic phenotype of sheep but not human P3 cells was rescued by addition of cryopreserved P0 chondrocytes. With bFGF supplementation, chondrocytes achieved clinically sufficient expansion at P2; COL2A1 expression was not rescued but COL1A1/3A1genes were downregulated. Although bFGF failed to rescue COL2A1 expression during chondrocyte expansion in vitro, elastic neocartilage with obvious collagen II expression was observed on porous collagen scaffolds after implantation in mice for 6 weeks. Conclusions: Both animal and human auricular chondrocytes expanded with low-concentration bFGF supplementation formed high-quality elastic neocartilage on porous collagen scaffolds in vivo

Isolation and Molecular Characterization of Circulating Melanoma Cells

Melanoma is an invasive malignancy with a high frequency of blood-borne metastases, but circulating tumor cells (CTCs) have not been readily isolated. We adapted microfluidic CTC capture to a tamoxifen-driven B-RAF/PTEN mouse melanoma model. CTCs were detected in all tumor-bearing mice and rapidly declined after B-RAF inhibitor treatment. CTCs were shed early from localized tumors, and a short course of B-RAF inhibition following surgical resection was sufficient to dramatically suppress distant metastases. The large number of CTCs in melanoma-bearing mice enabled a comparison of RNA-sequencing profiles with matched primary tumors. A mouse melanoma CTC-derived signature correlated with invasiveness and cellular motility in human melanoma. CTCs were detected in smaller numbers in patients with metastatic melanoma and declined with successful B-RAF-targeted therapy. Together, the capture and molecular characterization of CTCs provide insight into the hematogenous spread of melanoma