Progenitor cells in auricular cartilage demonstrate promising cartilage regenerative potential in 3D hydrogel culture

The reconstruction of auricular deformities is a very challenging surgical procedure that could benefit from a tissue engineering approach. Nevertheless, a major obstacle is presented by the acquisition of sufficient amounts of autologous cells to create a cartilage construct the size of the human ear. Extensively expanded chondrocytes are unable to retain their phenotype, while bone marrow-derived mesenchymal stromal cells (MSC) show endochondral terminal differentiation by formation of a calcified matrix. The identification of tissue-specific progenitor cells in auricular cartilage, which can be expanded to high numbers without loss of cartilage phenotype, has great prospects for cartilage regeneration of larger constructs. This study investigates the largely unexplored potential of auricular progenitor cells for cartilage tissue engineering in 3D hydrogels

Modeling, Design and Fabrication of Biocompatible Silk-Based Electronics and Actuators

Biocompatible actuators are widely desired for a variety of biomedical devices such as micromanipulators, steerable catheters and artificial muscles but current devices have shortcomings in the range of motion they can achieve. Biocompatible electrodes made from conducting polymers (CPs) have been successfully created but achieving the spatial patterning of these polymers needed for electronic devices like strain gauges, stimulation electrodes and micro circuitry has been difficult. Previous work has relied on complex chemical incorporation of CPs into photoresists or electropolymerization onto vapor-deposited metal substrates. A simple method to produce metal-free flexible electronics would be highly desirable for biomedical electronics. This work explores the use of photolithography to generate masks that can be used to create conductive CP patterns on the surface of fibroin films with resolution in the tens of microns. This process was used to create uniaxial strain gauges that achieved uniaxial sensitization and superior signal-to-noise over unpatterned films. Drop casting and laser etching were employed to give silk films defined surface topology and the mechanical characteristics and their performance as electrochemical actuators was studied. Electrochemical actuations were not significantly affected by the topological patterns, however the topological films demonstrated a promising ability to self-fold. Simulations of the electrochemical actuations by Finite Element Analysis modeling was made possible by creating an analogy of electrochemical expansion to thermal expansion. Analysis provided insight into previously inconclusive experimental results and suggested a further analogy between potential distribution and thermal distribution that leads to predictive models of both actuation and electrical polymerization

Biomaterials

This book provides an overview of biomaterials science with a focus on health and medical applications that can be improved with new biomaterials with non-allergenic elements. These materials are designed to meet functional requirements and overcome the disadvantages of classical alloys used as biomaterials in human tissue. Over seven chapters, this volume explains the problems created by classical alloys and examines how the new generation of biomaterials helps both doctors and patients. It is designed for students, doctors, patients, and researchers worldwide

Self-powered mobile sensor for in-pipe potable water quality monitoring

Traditional stationary sensors for potable-water quality monitoring in a wireless sensor network format allow for continuous data collection and transfer. These stationary sensors have played a key role in reporting contamination events in order to secure public health. We are developing a self-powered mobile sensor that can move with the water flow, allowing real-time detection of contamination in water distribution pipes, with a higher temporal resolution. Functionality of the mobile sensor was tested for detecting and monitoring pH, Ca2+, Mg2+, HCO3-/CO32-, NH4+, and Clions. Moreover, energy harvest and wireless data transmission capabilities are being designed for the mobile sensor

Human dermal fibroblast activation under pulsed electrical stimulation via conductive fabrics : signalling pathways and potential benefit for wound healing

Lors de la cicatrisation, plusieurs types cellulaires dont les kératinocytes et les fibroblastes ainsi que plusieurs facteurs de croissance jouent d’importants rôles. La cicatrisation cutanée peut aussi être activée par des facteurs exogènes, dont la stimulation électrique (SE). La SE peut moduler les fonctions fibroblastiques durant la cicatrisation. Le fibroblaste contribue de façon active à la cicatrisation en sécrétant différentes protéines (collagène, fibronectine, élastine) pour favoriser le comblement tissulaire. Les fibroblastes adoptent aussi un phénotype contractile en exprimant l’α-actine contribuant à la fermeture de la plaie. Notre hypothèse est que certaines de ces fonctions fibroblastiques pourraient être modulées par une stimulation électrique. Pour vérifier cette hypothèse nous avons utilisé une membrane biocompatible et conductrice à base de polyethylene terephthalate (PET) recouvert de polypyrrole (PPy). Les fibroblastes dermiques humains ont été cultivés sur ces membranes conducteurs, puis exposés ou non à un courant pulsé (PES) selon deux régimes : soit 10s PES suivi de 1200s de repos, ou 300s PES suivi de 600s de repos, durant 24 h. Deux intensités électriques ont été étudiées, 50 et 100 mV/mm. Nos travaux démontrent que la SE favorise l’adhésion, la prolifération et la migration des fibroblastes dermiques. Ces activités cellulaires sont consolidées par une sécrétion importante de FGF2 et d’α-SMA. Il est important de noter que l’effet de la SE favorise le changement phénotypique des fibroblastes en myo-fibroblastes grâce à la voie des Smad et de TGFβ/ERK. Nous avons aussi démontré que l’effet de la SE est maintenue à long terme et est transférable de la cellule mère vers les cellules filles. En effet après sous-culture les cellules expriment toujours de façon importante l’α-SMA. En conclusion, nous avons démontré que la stimulation électrique pulsée module positivement les fonctions cicatricielles des fibroblastes humains. Ces travaux démontrent pour la première fois les voies de signalisation (Smad et TGFβ/ERK) sollicitées par la SE pour activer les fibroblastes lors de la cicatrisation. Ces travaux suggèrent l’utilisation de la SE pour favoriser la guérison/cicatrisation des plaies.During skin wound healing, cutaneous cells particularly fibroblasts and keratinocytes as well as several growth factors play important roles. Wound healing can be activated by exogenous factors, including electrical stimulation (ES). ES can also modulate fibroblast functions. Fibroblasts contribute to healing by secreting structural proteins (collagen, fibronectin, elastin) to repair the wound area. Fibroblasts also adopt a contractile phenotype expressing α-actin contributing to wound closure. The hypothesis of the thesis is that fibroblasts proliferate and transdifferentiate into myofibroblasts by sensing pulsed electrical signals and adjusting relevant signalling pathways. To test this hypothesis we used biocompatible polyethylene terephthalate (PET) fabrics coated with electrically conductive polypyrrole (PPy). Human dermal fibroblasts were cultured on these conductive fabrics and exposed to the optimized pulsed ES: either 10s PES in a period of 1200s, or 300s PES in 600s period, for a total of 24 hours. Two electric intensities were studied, 50 and 100 mV/ mm. Our work showed that the PES promoted the adhesion, proliferation and migration of dermal fibroblasts. These cellular activities were consolidated by an elevated level of fibroblast growth factor 2 (FGF2) and the high expression of α-smooth muscle actin (α-SMA). Important findings were that PES promoted the phenotypic change of fibroblasts to myofibroblasts, and such change was coordinated through the Smad and TGFβ/ERK pathways. It also demonstrated that the effect of PES was able to maintain for a long period of time after the end of stimulation, and was transferable from the mother cells to the daughter cells. Following subculture, the electrically stimulated fibroblasts still expressed significant amount of α-SMA. In conclusion, this thesis demonstrates that PES through conductive fabrics can activate the wound healing functions in human dermal fibroblasts. This work revealed for the first time that Smad and TGFβ/ERK pathways are required by the PES-induced fibroblasts-to-myofibroblasts differentiation. This work also demonstrated that the PES activated cells can survive in vivo. These studies suggest the application of the PES in promoting tissue regeneration and wound healing

Biopolymers in Drug Delivery and Regenerative Medicine

Biopolymers including natural (e.g., polysaccharides, proteins, gums, natural rubbers, bacterial polymers), synthetic (e.g., aliphatic polyesters and polyphosphoester), and biocomposites are of paramount interest in regenerative medicine, due to their availability, processability, and low toxicity. Moreover, the structuration of biopolymer-based materials at the nano- and microscale along with their chemical properties are crucial in the engineering of advanced carriers for drug products. Finally, combination products including or based on biopolymers for controlled drug release offer a powerful solution to improve the tissue integration and biological response of these materials. Understanding the drug delivery mechanisms, efficiency, and toxicity of such systems may be useful for regenerative medicine and pharmaceutical technology. The main aim of the Special Issue on “Biopolymers in Drug Delivery and Regenerative Medicine” is to gather recent findings and current advances on biopolymer research for biomedical applications, particularly in regenerative medicine, wound healing, and drug delivery. Contributions to this issue can be as original research or review articles and may cover all aspects of biopolymer research, ranging from the chemical synthesis and characterization of modified biopolymers, their processing in different morphologies and hierarchical structures, as well as their assessment for biomedical uses