An experimental model to mimic the mechanical behavior of a scaffold in a cartilage defect

[EN] Abstract The main purpose of this thesis is the design and characterization of an experimental articular cartilage model. The in vitro model is composed of a macro and micro- porous Polycaprolactone scaffold with a Poly(Vinyl Alcohol) filling. The scaffold/hydrogel construct has been subjected to repeating number of freezing and thawing cycles in order to crosslink the hydrogel inside the scaffold's pores. The Poly(Vinyl Alcohol) resembles the growing cartilaginous tissue inside the scaffolds pores, as it gets denser and stiffer for each cycle of freezing and thawing. The in vitro model allows studying a variety of characteristics of the scaffold and hydrogel, revealing interesting features. The importance of water flow on the mechanical properties is studied, so as the influence of micro-porosity. It can be seen that the mechanical properties of the porous scaffolds are influenced in distinct ways by the hydrogel density and micro-porosity of the scaffold. The permeability of the scaffolds is studied and is seen independent of crosslinking density of the hydrogel inside the porous scaffolds. The experimental cartilage model has also been applied on a macro porous acrylic scaffold. The results show that the water has different effect on the mechanical properties, for macro, or macro and micro-porous scaffolds. The in vitro cartilage model has elastic modulus, aggregate modulus and permeability values in the same order as human articular cartilage. The model is useful to predict the mechanical behavior of porous scaffolds in vivo. A scaffold implant device for animal studies has been designed based on a previous patent of the research group, and implanted in two different in vivo trials in sheep. The results show that the fixation and anchoring to the subchondral bone improve the tissue repair and diminish alterations in the subchondral bone. ¿[ES] Resumen El objetivo principal de esta tesis doctoral es el diseño y caracterización de un modelo de cartílago articular experimental. El modelo in vitro se compone de un scaffold micro- y macroporoso de Policaprolactona con un relleno de Poli(Vinil Alcohol). El constructo scaffold/hidrogel ha sido sometido a ciclos consecutivos de congelación y descongelación con objeto de entrecruzar el hidrogel dentro de los poros del scaffold. El Poli(Vinil Alcohol) mimetiza al tejido de cartílago que se regenerará en los poros, ya que en cada ciclo de congelación y descongelación se vuelve más denso y duro. El modelo in vitro permite estudiar una gran variedad de características del scaffold e hidrogel, revelando fenómenos interesantes para la ingeniería tisular. Se ha estudiado la importancia del flujo de agua a través del scaffold en las propiedades mecánicas, así como la influencia de la microporosidad. Se ha podido constatar que la densidad del hidrogel y la microporosidad influyen de distinta forma en las propiedades mecánicas de los scaffolds porosos. Se ha estudiado la permeabilidad de los scaffolds, que ha resultado ser independiente de la densidad de entrecruzamiento del hidrogel dentro de sus poros. El modelo experimental de cartílago se ha aplicado también a un scaffold macroporoso acrílico. Los resultados muestran que el agua tiene un efecto distinto en las propiedades mecánicas de los scaffolds macroporosos y en los micro- macroporosos. El modelo de cartílago in vitro tiene valores del modulo elástico, módulo agregado y permeabilidad que son del mismo orden de magnitud que los del cartílago articular humano. El modelo permite predecir el comportamiento mecánico in vivo de scaffolds porosos. Se ha diseñado un dispositivo de implante de scaffold para experimentos en animales basado en una patente del grupo de investigación, que ha sido implantado en dos ensayos in vivo diferentes en ovejas. Los resultados muestran que la fijación y anclaje al hueso subcondral tiene un gran papel en la reparación del tejido.[CA] Resum L'objectiu principal d'aquesta tesi doctoral és el disseny i caracterització d'un model de cartílag articular experimental. El model in vitro es compon d'un scaffold micro- i macroporós de Policaprolactona amb un farciment de Poli(Vinil Alcohol). El constructe scaffold/hidrogel ha estat sotmès a cicles consecutius de congelació i descongelació amb l'objectiu d'entrecreuar l'hidrogel dins del porus del scaffold. El Poli(Vinil Alcohol) mimetitza al teixit de cartílag que es regenerarà en el porus, ja que en cada cicle de congelació i descongelació es torna més dens i dur. El model in vitro permet estudiar una gran varietat de característiques del scaffold i hidrogel, posant de manifest fenòmens interessants per a l'enginyeria tissular. S'ha estudiat la importància del flux d'aigua a través del scaffold en les propietats mecàniques, així com la influència de la microporositat. S'ha pogut constatar que la densitat de l'hidrogel i la microporositat influeixen de distinta manera en les propietats mecàniques dels scaffolds porosos. S'ha estudiat la permeabilitat dels scaffolds, que ha resultat ser independent de la densitat d'entrecreuament de l'hidrogel dins dels seus porus. El model experimental de cartílag s'ha aplicat també a un scaffold macroporós acrílic. Els resultats mostren que l'aigua té un efecte distint en les propietats mecàniques dels scaffolds macroporosos i en els micro- macroporosos. El model de cartílag in vitro té valors del mòdul elàstic, mòdul agregat i permeabilitat que són del mateix ordre de magnitud que els del cartílag articular humà. El model permet predir el comportament mecànic in vivo de scaffolds porosos. S'ha dissenyat un dispositiu d'implant de scaffold per a experiments en animals basat en una patent del grup d'investigació, que ha segut implantat en dos assaigs in vivo diferents en ovelles. Els resultats mostren que la fixació i ancoratge a l'os subcondral té un gran paper en la reparació del teixit.Vikingsson, LKA. (2015). An experimental model to mimic the mechanical behavior of a scaffold in a cartilage defect [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/53912TESI

Grid polymeric scaffolds with polypeptide gel filling as patches for infarcted tissue regeneration

© 2013 IEEE. Personal use of this material is permitted. Permissíon from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertisíng or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works.[EN] Scaffolds of poly(ethyl acrylate) (PEA) with interconnected cylindrical orthogonal pores filled with a self-assembling peptide (SAP) gel are here proposed as patches for infarcted tissue regeneration. These combined systems aim to support cell therapy and meet further requirements posed by the application: the three-dimensional architecture of the elastomeric scaffold is expected to lodge the cells of interest in the damaged zone avoiding their death or migration, and at the same time conduct cell behavior and give mechanical support if necessary; the ECM-like polypeptide gel provides a cell-friendly aqueous microenvironment, facilitates diffusion of nutrients and cell wastes and is expected to improve the distribution and viability of the seeded cells within the pores and stimulate angiogenesis.Research supported by the European Comission through the RECATABI FP7 NMP3-SL-2009-229239 project and the spanish Ministerio de Ciencia e Innovación through the MAT2011-28791-C03-02 and -03 projects.Vallés Lluch, A.; Arnal Pastor, MP.; Martínez-Ramos, C.; Vilariño, G.; Vikingsson, L.; Monleón Pradas, M. (2013). Grid polymeric scaffolds with polypeptide gel filling as patches for infarcted tissue regeneration. Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 6961-6964. https://doi.org/10.1109/EMBC.2013.6611159S6961696

Local deformation in a hydrogel induced by an external magnetic field

The aim of this study is to prove the feasibility of a system able to apply local mechanical loading on cells seeded in a hydrogel for tissue engineering applications. This experimental study is based on a previously developed artificial cartilage model with different concentrations of poly(vinyl alcohol) (PVA) that simulates the cartilage extracellular matrix (ECM). Poly(l-lactic acid) (PLLA) microspheres with dispersed magnetic nanoparticles (MNPs) were produced with an emulsion method. These microspheres were embedded in aqueous PVA solutions with varying concentration to resemble increased viscosity of growing tissue during regeneration. The ability to induce a local deformation in the ECM was assessed by applying a steady or an oscillatory magnetic field gradient to different PVA solutions containing the magnetic microparticles, similarly as in ferrogels. PLLA microparticle motion was recorded, and the images were analyzed. Besides, PVA gels and PLLA microparticles were introduced into the pores of a polycaprolactone scaffold, and the microparticle distribution and the mechanical properties of the construct were evaluated. The results of this experimental model show that the dispersion of PLLA microparticles containing MNPs, together with cells in a supporting gel, will allow applying local mechanical stimuli to cells during tissue regeneration. This local stimulation can have a positive effect on the differentiation of seeded cells and improve tissue regeneration.The authors gratefully acknowledge the financial support from the Spanish Ministry of Economy and Competitiveness through the MAT2013-46467-C4-1-R project, including the Feder funds. CIBER-BBN is an initiative funded by the VI National R&D&I Plan 2008-2011, Iniciativa Ingenio 2010, Consolider Program. CIBER Actions are financed by the Instituto de Salud Carlos III with assistance from the European Regional Development Fund. The authors thank "Servicio de Microscopia Electronica" of Universitat Politecnica de Valencia for their invaluable help. The translation of this paper was funded by the Universitat Politecnica de Valencia, Spain.Vikingsson, L.; Vinals Guitart, Á.; Valera Martínez, A.; Riera Guasp, J.; Vidaurre Garayo, AJ.; Gallego Ferrer, G.; Gómez Ribelles, JL. (2016). Local deformation in a hydrogel induced by an external magnetic field. Journal of Materials Science. 51(22):9979-9990. https://doi.org/10.1007/s10853-016-0226-8S997999905122Eyre D (2002) Collagen of articular cartilage. Arthritis Res 4:30–35Roughley PJ, Lee ER (1994) Cartilage proteoglycans: structure and potential functions. Microsc Res Tech 28:385–397Gillard GC, Reilly HC, Bell-Booth PG, Flint MH (1979) The influence of mechanical forces on the glycosaminoglycan content of the rabbit flexor digitorum profundus tendon. Connect Tissue Res 7:37–46Quinn TM, Grodzinsky AJ, Buschmann MD, Kim YJ, Hunziker EB (1998) Mechanical compression alters proteoglycan deposition and matrix deformation around individual cells in cartilage explants. J Cell Sci 111:573–583Banes AJ, Tsuzaki M, Yamamoto J, Fischer T, Brigman B, Brown T, Miller L (1995) Mechanoreception at the cellular level: the detection, interpretation, and diversity of responses to mechanical signals. Biochem Cell Biol 73:349–365Appelman T, Mizrahi J, Elisseeff J, Seliktar D (2011) The influence of biological motifs and dynamic mechanical stimulation in hydrogel scaffold systems on the phenotype of chondrocytes. Biomaterials 32:1508–1516Mow VC, Ratcliffe A, Poole AR (1992) Cartilage and diarthrodial joints as paradigms for hierarchical materials and structures. Biomaterials 13:67–97Mow VC, Huiskes R (2005) Basic orthopaedic biomechanics and mechano-biology. Lippincott Williams and Wilkins, PhiladelphiaBrady MA, Waldman SD, Ethier CR (2015) The application of multiple biophysical cues to engineer functional neocartilage for treatment of osteoarthritis. Part I: cellular response. Tissue Eng Part B Rev 21:1–19Valhmu WB, Stazzone EJ, Bachrach NM, Saed-Nejad F, Fischer SG, Mow VC, Ratcliffe A (1998) Load-controlled compression of articular cartilage induces a transient stimulation of aggrecan gene expression. Arch Biochem Biophys 353:29–36Ingber DE (1997) Tensegrity: the architectural basis of cellular mechanotransduction. Ann Rev Physiol 59:575–599Khan S, Sheetz MP (1997) Force effects on biochemical kinetics. Ann Rev Biochem 66:785–805Hutmacher DW (2000) Scaffolds in tissue engineering bone and cartilage. Biomaterials 21:2529–2543Crick FHC, Hughes AFW (1950) The physical properties of cytoplasm: a study by means of the magnetic particle method. Exp Cell Res 1:37–80Valberg PA, Albertini DF (1985) Cytoplasmic motions, rheology, and structure probed by a novel magnetic particle method. J Cell Biol 101:130–140Valberg PA, Feldman HA (1987) Magnetic particle motions within living cells. Measurement of cytoplasmic viscosity and motile activity. Biophys J 52:551–561Wang N, Ingber DE (1995) Probing transmembrane mechanical coupling and cytomechanics using magnetic twisting cytometry. Biochem Cell Biol 73:327–335Pommerenke H, Schreiber E, Durr F, Nebe B, Hahnel C, Moller W, Rychly J (1996) Stimulation of integrin receptors using a magnetic drag force device induces an intracellular free calcium response. Eur J Cell Biol 70:157–164Bausch AR, Hellerer U, Essler M, Aepfelbacher M, Sackmann E (2001) Rapid stiffening of integrin receptor-actin linkages in endothelial cells stimulated with thrombin: a magnetic bead microrheology study. Biophys J 80:2649–2657Li L, Yang G, Li J, Ding S, Zhou S (2014) Cell behaviors on magnetic electrospun poly-d, l-lactide nano fibers. Mater Sci Eng, C 34:252–261Fuhrer R, Hofmann S, Hild N, Vetsch JR, Herrmann IK, Grass RN, Stark WJ (2013) Pressureless mechanical induction of stem cell differentiation is dose and frequency dependent. PLoS One 8:e81362Cezar CA, Roche ET, Vandenburgh HH, Duda GN, Walsh CJ, Mooney DJ (2016) Biologic-free mechanically induced muscle regeneration. Proc Natl Acad Sci USA 113:1534–1539Vikingsson L, Gallego Ferrer G, Gómez-Tejedor JA, Gómez Ribelles JL (2014) An in vitro experimental model to predict the mechanical behaviour of macroporous scaffolds implanted in articular cartilage. J Mech Behav Biomed Mater 32:125–131Vikingsson L, Gomez-Tejedor JA, Gallego Ferrer G, Gomez Ribelles JL (2015) An experimental fatigue study of a porous scaffold for the regeneration of articular cartilage. J Biomech 48:1310–1317Vikingsson L, Claessens B, Gómez-Tejedor JA, Gallego Ferrer G, Gómez Ribelles JL (2015) Relationship between micro-porosity, water permeability and mechanical behavior in scaffolds for cartilage engineering. J Mech Behav Biomed Mater 48:60–69Li F, Su YL, Shi DF, Wang CT (2010) Comparison of human articular cartilage and polyvinyl alcohol hydrogel as artificial cartilage in microstructure analysis and unconfined compression. Adv Mater Res Trans Tech Publ 87:188–193Grant C, Twigg P, Egan A, Moody A, Eagland D, Crowther N, Britland S (2006) Poly(vinyl alcohol) hydrogel as a biocompatible viscoelastic mimetic for articular cartilage. Biotechnol Prog 22:1400–1406Weeber R, Kantorovich S, Holm C (2015) Ferrogels cross-linked by magnetic nanoparticles—Deformation mechanisms in two and three dimensions studied by means of computer simulations. J Magn Magn Mater 383:262–266Lebourg M, Suay Antón J, Gómez Ribelles JL (2008) Porous membranes of PLLA–PCL blend for tissue engineering applications. Eur Polym J 44:2207–2218Santamaría VA, Deplaine H, Mariggió D, Villanueva-Molines AR, García-Aznar JM, Gómez Ribelles JL, Doblaré M, Gallego Ferrer G, Ochoa I (2012) Influence of the macro and micro-porous structure on the mechanical behavior of poly (l-lactic acid) scaffolds. J Non Cryst Solids 358:3141–3149Panadero JA, Vikingsson L, Gomez Ribelles JL, Lanceros-Mendez S, Sencadas V (2015) In vitro mechanical fatigue behaviour of poly-ε-caprolactone macroporous scaffolds for cartilage tissue engineering. Influence of pore filling by a poly(vinyl alcohol) gel. J Biomed Mater Res Part B Appl Biomater 103:1037–1043Hassan CM, Peppas NA (2000) Structure and applications of poly(vinyl alcohol) hydrogels produced by conventional crosslinking or by freezing/thawing methods. Adv Polym Sci 153:37–65Labet M, Thielemans W (2009) Synthesis of polycaprolactone: a review. Chem Soc Rev 38:3484–3504Mano JF, Gómez Ribelles JL, Alves NM, Salmerón Sanchez M (2005) Glass transition dynamics and structural relaxation of PLLA studied by DSC: influence of crystallinity. Polymer 46:8258–8265Eckstein F, Lemberger B, Gratzke C, Hudelmaier M, Glaser C, Englmeier KH, Reiser M (2005) In vivo cartilage deformation after different types of activity and its dependence on physical training status. Ann Rheum Dis 64:291–295Garlotta D (2001) A literature review of poly(lactic acid). J Polym Eng 9:63–84Kovacs AJ, Aklonis JJ, Hutchinson JM, Ramos AR (1979) Isobaric volume and enthalpy recovery of glasses. II. A transparent multiparameter theory. J Polym Sci Polym Phys 17:1097–1162Hernández F, Molina Mateo J, Romero Colomer F, Salmerón Sánchez M, Gómez Ribelles JL, Mano J (2005) Influence of low-temperature nucleation on the crystallization process of poly(l-lactide). Biomacromolecules 6:3291–3299Wang Y, Gómez Ribelles JL, Salmerón Sánchez M, Mano JF (2005) Morphological contribution to glass transition in poly(l-lactic acid). Macromolecules 38:4712–4718Salmerón Sánchez M, Vincent BM, Vanden Poel G, Gómez-Ribelles JL (2007) Effect of the cooling rate on the nucleation kinetics of poly(l-lactic acid) and its influence on morphology. Macromolecules 40:7989–7997Nobuyuki O (1975) A threshold selection method from gray-level histograms. Automatica 11:23–2

Relationship between micro-porosity, water permeability and mechanical behavior in scaffolds for cartilage engineering

In tissue engineering the design and optimization of biodegradable polymeric scaffolds with a 3D-structure is an important field. The porous scaffold provide the cells with an adequate biomechanical environment that allows mechanotransduction signals for cell differentiation and the scaffolds also protect the cells from initial compressive loading. The scaffold have interconnected macro-pores that host the cells and newly formed tissue, while the pore walls should be micro-porous to transport nutrients and waste products. Polycaprolactone (PCL) scaffolds with a double micro- and macro-pore architecture have been proposed for cartilage regeneration. This work explores the influence of the micro-porosity of the pore walls on water permeability and scaffold compliance. A Poly(Vinyl Alcohol) with tailored mechanical properties has been used to simulate the growing cartilage tissue inside the scaffold pores. Unconfined and confined compression tests were performed to characterize both the water permeability and the mechanical response of scaffolds with varying size of micro-porosity while volume fraction of the macro-pores remains constant. The stress relaxation tests show that the stress response of the scaffold/ hydrogel construct is a synergic effect determined by the performance of the both components. This is interesting since it suggests that the in vivo outcome of the scaffold is not only dependent upon the material architecture but also the growing tissue inside the scaffold's pores. On the other hand, confined compression results show that compliance of the scaffold is mainly controlled by the micro-porosity of the scaffold and less by hydrogel density in the scaffold pores. These conclusions bring together valuable information for customizing the optimal scaffold and to predict the in vivo mechanical behavior.The authors gratefully acknowledge the financial support from the Spanish Ministry of Economy and Competitiveness through the MAT2013-46467-C4-1-R project, including FEDER funds. CIBER-BBN is an initiative funded by the VI National R&D&I Plan 2008-2011, Iniciativa Ingenio 2010, Consolider Program, CIBER Actions and financed by the Instituto de Salud Carlos III with the assistance from the European Regional Development Fund.Vikingsson, LKA.; Claessens, B.; Gómez Tejedor, JA.; Gallego Ferrer, G.; Gómez Ribelles, JL. (2015). Relationship between micro-porosity, water permeability and mechanical behavior in scaffolds for cartilage engineering. Journal of the Mechanical Behavior of Biomedical Materials. 48:60-69. https://doi.org/10.1016/j.jmbbm.2015.03.021S60694