1

Introduction

In 1969, Hench et al. developed a new material for medical applications; creating a solid base for the following 40 years of research in the bone/tissue regeneration field. 45S5 was the first bioactive glass generated, with a composition showing an excellent biocompatibility. Its composition by weight is: 45% SiO ₂ , 24.5% Na ₂ O, 24.5% CaO and 6% P ₂ O ₅ . This material is able to bond with bone and stimulates bone growth due to hydroxy-carbonate apatite (HCA) formation. This type of apatite is chemically and structurally very similar to the mineral phase of hard tissues.

Bonding to bone and tissues has been well documented and investigated by a large series of bioactive glass compositions . The mechanism of bone bonding enables the bioglass (BG) to develop an adherent interface with tissues that resists mechanical forces. In many cases, the interfacial strength of adhesion is equivalent to or greater than the cohesive strength of the implanted material or the tissue bonded to the bioactive implant. Five steps have been described for bone-bounding mechanism in bioactive glass :

• •

  Step 1: fast release of Na ⁺ and Ca ²⁺ ions which are exchanged with the H ₃ O ⁺ ions present in the solution. A rapid increase of solution pH develops.

• •

  Step 2: network silica is attacked by hydroxyl groups causing the formation of Si(OH) ₄ in the solution.

• •

  Step 3: Silanols (−Si OH groups) form a silica rich layer on the surface thanks to re-polymerization reactions.

• •

  Step 4: Ca ²⁺ and PO ₄ ³⁻ migrate to the newly formed silica surface forming a CaO–P ₂ O ₅ film on top.

• •

  Step 5: CaO–P ₂ O ₅ film crystallize and incorporate other ions from the solution (such as OH ⁻ and CO ₃ ⁻ ) will form a HCA layer.

For the treatment of bone defects or dental trauma as well as diseases such as osteoporosis, cancer and infectious diseases, it is essential to develop new active materials that are able to interact with host surroundings, enhancing and directing complete tissue healing, repair and regeneration. Synthetic biocompatible materials are used to replace damaged tissues but the weakness of some chemical, biological and/or physical properties results in implant failure that requires retreatment.

The original 45S5 bioglass has been already used in different materials for repairing bone defects in the jaw and orthopaedics. Bioactive glass grafts were originally developed for replacing ear bones and alveolar bone defects around teeth; the products used were based on particles rather than monolithic shape, i.e . PerioGlas ^® and NovaBone ^® . Micro and nano-particles have superior bioactive behaviours due to a larger specific surface area that allows a faster ion release. Bioactive coatings are likewise very important for metallic implants because they have the potential to improve their performance by providing strong bonding to the host bone and to the resin cement . Nevertheless, 45S5 bioglasses are applied also to non-permanent materials especially used in dentistry. BG-pastes are favourable for the treatment of dentin hypersensitivity , enamel demineralization and for tooth bleaching . Finally, bioactive glasses have satisfying characteristics as a scaffold material for bone tissue engineering, but the application of glass scaffolds for the load-bearing bone defects reparation is often limited by their low mechanical strength and fracture toughness.

Despite the excellent biological properties, mainly osteoblast proliferation and differentiation induced by the released ions by the material, bioglasses are brittle materials that are easily cracked. This low strength and fracture toughness prevents their use for load-bearing implants . The development of new glass compositions with improved mechanical properties is a challenging objective and the trend is to incorporate different elements to obtain better biological and physical characteristics. Crystallinity significantly changes the fracture characteristics of glasses. This opens the way for glass-ceramics as offerings with improved mechanical properties. On the other hand, the introduction of crystalline phases could decrease the bioactivity. Several attempts have been made to preserve the amorphous structure of the glass with the addition of silver, magnesium, strontium, boron, zinc, aluminium, fluoride, potassium, gallium, barium and zirconia. Addition of silver and boron have been investigated in order to improve the strength and develop antibacterial and antimicrobial materials; magnesium has stimulatory effects on the growth of new bony tissues ; calcium is shown to be responsible for osteoblast proliferation , while elements like zirconia improve the mechanical properties but decrease the bioactivity behaviour .

In recent years, bioactive glass particles have been introduced as fillers in conventional composites for tissue engineering, mixing them with polymers such as polylactic acid (PLA), polyglycolic acid (PGA) and their copolymer poly l (lactic- co -glycolic) acid (PLGA). Composite scaffolds for bone tissue engineering have been studied to obtain materials that impart better mechanical and physiological properties to the host tissue. Polymer/bioactive glass composite scaffolds show especially an increase in bioactivity which is achieved by the bioglass inclusion. The degree of bioactivity is adjustable by the volume of fraction, size, shape and arrangement of this inclusion. It has been shown that increased volume fraction and higher surface areas to volume ratio favour higher bioactivity; incorporation of fibres as fillers (instead of particles) enhances the mechanical properties. The dissolution of the bioactive glass should result in nucleation and growth of a crystalline HCA layer on the surface of the polymer scaffold, which should further affect the polymer degradation behaviour in addition to provide the required osteoconductivity. Thus, a combination of polymers and bioactive glass phases result in promising composite scaffolds for (bone) tissue engineering. Finally, it is clear that the chemistry and physical properties of the added polymer and bioactive glass have a significant incidence on mechanical properties and consequently in material degradation .

Several families of bioactive glasses have been more precisely investigated:

• •

  Silicate-based glasses, like 45S5, are glasses where silica (SiO ₂ ) is the classic network-former. The basic unit is the SiO ₄ tetrahedron capable of sharing up to 4 oxygen atoms with other such tetrahedral units or other elements. Silicon has a charge of 4+.

• •

  Phosphate-based glasses in the system CaO–Na ₂ O–P ₂ O ₅ have the tetrahedral structure formed by PO ₄ units and the phosphate group has a charge of 5 ⁺ . Therefore, they contain at least one terminal oxygen that limits connectivity and so the reactivity of the structure that gives unique dissolution properties in aqueous-based fluids for these types of glasses.

• •

  Borate-based glasses are based on a B ₂ O ₃ network that can occur both in triangular and tetrahedral coordination but mostly in the triangular form especially vitreous compounds. Borate glasses show potential in bone regeneration owning to its complete conversion to apatite through a series of dissolution-precipitation reaction similar to those of 45S5 bioglass.

The purpose of this literature review is to assess the mechanical and biological properties of bioactive glasses used for dental and medical applications regarding their compositions.

2

Materials and methods

PRISMA guidelines for systematic review and meta-analysis have been used for this review manuscript . A literature search was performed using several electronic databases (PubMed, ScienceDirect) on articles published in the last 5 years, to identify the most recent developments on the subject. The research took place on 1st March 2016 in the Faculté d’Odontologie, Université Claude Bernard Lyon 1, Lyon, France. To be included, papers had to consist of both physical properties and biological properties or at least physical properties as these studies had to provide valid information in order to compare the various results obtained in the different studies. Language restrictions were not applied. Furthermore, these studies had to meet the following criteria:

• 1.

  Bioactive glasses used in medicine.

• 2.

  Evaluation of mechanical and biological properties.

The terms used in the search (in Title/Abstract) were as follows:

(“Bioglass*” AND “Biological properties”)

OR

(“Bioglass*” AND “Physical properties”).

Review articles and short communications were excluded. Two reviewers (FL and CV) screened accurately and independently all the titles and abstracts. The full texts of all the articles in accordance with the inclusion criteria (by consensus) were collected and reviewed. Also all the reference citations were screened for any relevant publications that might have been missed by the electronic search and that could be relevant for the current report. Finally, a consensus between the two readers was reached to determine which studies met the selection criteria.

2

Materials and methods

PRISMA guidelines for systematic review and meta-analysis have been used for this review manuscript . A literature search was performed using several electronic databases (PubMed, ScienceDirect) on articles published in the last 5 years, to identify the most recent developments on the subject. The research took place on 1st March 2016 in the Faculté d’Odontologie, Université Claude Bernard Lyon 1, Lyon, France. To be included, papers had to consist of both physical properties and biological properties or at least physical properties as these studies had to provide valid information in order to compare the various results obtained in the different studies. Language restrictions were not applied. Furthermore, these studies had to meet the following criteria:

• 1.

  Bioactive glasses used in medicine.

• 2.

  Evaluation of mechanical and biological properties.

The terms used in the search (in Title/Abstract) were as follows:

(“Bioglass*” AND “Biological properties”)

OR

(“Bioglass*” AND “Physical properties”).

Review articles and short communications were excluded. Two reviewers (FL and CV) screened accurately and independently all the titles and abstracts. The full texts of all the articles in accordance with the inclusion criteria (by consensus) were collected and reviewed. Also all the reference citations were screened for any relevant publications that might have been missed by the electronic search and that could be relevant for the current report. Finally, a consensus between the two readers was reached to determine which studies met the selection criteria.

3

Results