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Mineralized hydrogels for bone regeneration

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Konferencja
Biomaterials in medicine and veterinary medicine : 25th anniversary conference : 13-16 October 2016, Rytro, Poland
Języki publikacji
EN
Abstrakty
EN
Biomaterials for bone regeneration have predominantly been fabricated from inorganic substances such as various forms of calcium phosphate (CaP), e.g. hydroxyapatite, tricalcium phosphate and brushite. CaP materials are mechanical stable and bioactive, i.e. they form a direct bone with surrounding bone tissue. However, such pure CaP materials have certain drawbacks. They are brittle, difficult to handle in granulate form and difficult to shape in block form. Furthermore, the incorporation of biologically active substances is not easy. Hydrogels are highly hydrated three-dimensional polymer networks that are formed by crosslinking of polymer chains in solution. Hydrogels have been widely used as vehicles for drug delivery and are being used increasingly as biomaterials for tissue regeneration. As their main component is water, they have many advantages over pure inorganic materials. Firstly, the incorporation of water-soluble biologically active substances to promote tissue growth (e.g. growth factors) or to combat infection (e.g. antibiotics) is straightforward. Secondly, they are much less brittle. Thirdly, they can be implanted in a minimally invasive manner by injection, as they can undergo gelation, i.e. the transition from liquid to solid, after injection. However, their main disadvantage also stems from the fact that the mail component is water: hydrogels are mechanically weak. In order to combine the advantages of inorganic and hydrogel biomaterials, attention has recently been focused on the development of composites on the basis of mineralized hydrogels. Several strategies have been tried [1]. The most common strategy is the addition of preformed inorganic particles to the polymer solution before gelation, after which the particles remain entrapped in the crosslinked polymer network. Ideally, the particles can be distributed homogeneously in the hydrogel. The gelation process can be induced by addition of inorganic particles. For example, the addition of bioactive glass particles to a solution of the anionic polysaccharide gellan gum results in hydrogel formation due to release of ions from the particles [2]. In other words, the particles serve as an “ion-delivery system” to provide homogeneous gelation. Another strategy is to promote precipitation of the inorganic phase in the hydrogel by increasing the concentration of ions. This can be achieved biomimetically using the enzyme alkaline phosphatase (ALP) which is responsible for the mineralization of bone tissue in vivo by cleaving phosphate ions from organophosphate and thus increasing the local phosphate concentration, which in turn promotes CaP precipitation [3]. Yet another strategy is the incorporation of calcium- or phosphate-binding molecules in the hydrogel, in order to increase localion concentrations and promote CaP precipitation. Once such biomolecule is polydopamine, which binds calcium ions [4]. An added flexibility of mineralized hydrogels is the possibility of manipulation of either the hydrogel phase, or the inorganic phase, or both. For example, in the case of a hydrogel mineralized with CaP, the inorganic phase may be modified by incorporation of magnesium in order to promote adhesion and proliferation of bone-forming cells [5], or by incorporation of zinc in order to endow antibacterial activity [6]. Alternatively, the hydrogel phase may be modified by incorporation of biologically active molecules such as polyphenols, which both bind calcium ions and exhibit antibacterial activity [7]. Mineralization strategies will be illustrated on the basis of previous work [1-7].
Słowa kluczowe
Rocznik
Strony
8
Opis fizyczny
Bibliogr. 7 poz.
Twórcy
  • Department of Molecular Biotechnology, Faculty of Bioscience Engineering, Ghent University, Belgium
Bibliografia
  • [1] Gkioni K, Leeuwenburgh SC, Douglas TE et al. Tissue Eng Part B Rev. 2010 Dec;16(6):577-85
  • [2] Douglas TE, Piwowarczyk W, Pamula E et al. et al. Biomed Mater. 2014 Aug;9(4):045014.
  • [3] Douglas TE, Messersmith PB, Chasan S et al. Macromol Biosci. 2012 Aug;12(8):1077-89.
  • [4] Douglas TE, Wlodarczyk M, Pamula E, et al. J Tissue Eng Regen Med. 2014 Nov;8(11):906-18.
  • [5] Douglas TE, Krawczyk G, Pamula E et al. J Tissue Eng Regen Med. 2014 Feb 21. doi: 10.1002/term.1875. [Epub]
  • [6] Douglas TE, Pilarz M, Lopez-Heredia MA et al. J Tissue Eng Regen Med. 2015 Jul 15. doi: 10.1002/term.2062. [Epub]
  • [7] Douglas TE, Dokupil A, Reczyńska K et al. Biomed Mater 2016 Aug 10 dx.doi.org/10.1088/1748- 6041/11/4/045015. [Epub]
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-539849ac-0ab4-4f2c-95f7-231a80412dfc
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