Applications of Smart Multifunctional Tissue Engineering Scaffolds

M. KALIVA, M. CHATZINIK0LAIDOU M. VAMVAKAKI

1.1 Introduction

Tissue engineering is an attractive approach to restore and replace diseased or defective tissue offering an alternative to other clinical methods such as organ replacement. Conventional tissue engineering approaches involve the use of a scaffold mainly as a structural element with defined physicochemical, mechanical and biological properties and appropriate architecture and porosity to support cell metabolism. However, recent approaches in tissue regeneration combine three key elements: a scaffold as a micro-environment to promote cell adhesion for tissue development, an appropriate cell type, and biomolecules and drugs to guide cell response and function. There has been enormous interest lately in the growth of different types of tissues using multifunctional scaffolds that can actively participate in the process to provide the biological signals that guide and direct cell function (proliferation, growth and differentiation). Such scaffolds are derived from novel functional and smart materials that allow tuning of the properties and behavior of the scaffolds and can perform multiple crucial tasks simultaneously i.e. deliver bioactive and pharmaceutical molecules, direct cell growth and differentiation, and control stem cell behavior.

Organic, inorganic and hybrid (organic-inorganic) materials have all been explored in the development of multifunctional scaffolds. Basic material requirements for use in tissue engineering include biocompatibility, histocompatibility, non-toxicity and the ability to engineer an appropriate scaffold with the required functionalities.

Multifunctional scaffolds based on smart materials have been applied in different tissue engineering fields. The most frequently studied areas in the literature include the use of multifunctional scaffolds in bone, cartilage and muscle formation, in cardiovascular and endothelium tissue engineering, in the growth of skin and in neural regeneration. Other applications include their use in dental, corneal and retina tissue engineering as well as in wound healing. This chapter will focus on the most extensively studied tissues of which the understanding and knowledge have matured the most. Although multifunctional materials and stimuli-sensitive nanoparticulate drug delivery systems have also shown great therapeutic potential for various cardiovascular and infectious diseases and cancer, this application will not be discussed here. In the following, the sections are divided based on the respective tissue of interest, for which the material characteristics and the multifunctionality of materials and scaffolds are discussed (Figure 1.1). The potential clinical applications of the multifunctional scaffolds are also considered.

1.2 Applications of Multifunctional Scaffolds in Tissue Engineering

1.2.1 Bone and Cartilage

Bone is a remarkably organized, hierarchical connective and vascularized tissue that provides mechanical support and serves various biological functions. Degenerative diseases, cancer or injury can cause bone defects. Despite the impressive ability of bone to heal spontaneously after trauma or fractures, a significant need still exists to develop strategies that promote the healing of non-spontaneously healed defects as a result of sufficiently large fractures or diseases with poor healing ability (i.e. osteoporosis, cancer). Bone tissue regeneration is a physiological and complex procedure that involves a well-orchestrated participation of various bioactive molecules. Bone extracellular matrix (ECM) comprises different proteins such as collagen fibronectin (FN), osteocalcin (OC), osteopontin (OPN), and bone sialoprotein (BSP). Different bone morphogenetic proteins (BMps) and growth factors, like transforming growth factor-beta (TGF-ß), insulin-like growth factor (IGF), platelet-derived growth factor (PDGF), fibroblast growth factor (FGF), and vascular endothelial growth factor (VEGF), are actively involved in the process of bone regeneration, in a spatiotemporal and concentration-controlled manner. Multifunctional scaffolds, based on smart materials, are capable of promoting new bone formation, and have received particular attention in the field of bone...