Control of the thermal properties of slow bioresorbable glasses by boron addition

A1 Originalartikel i en vetenskaplig tidskrift (referentgranskad)


Interna författare/redaktörer


Publikationens författare: Massera J, Claireaux C, Lehtonen T, Tuominen J, Hupa L, Hupa M
Förläggare: ELSEVIER SCIENCE BV
Publiceringsår: 2011
Tidskrift: Journal of Non-Crystalline Solids
Tidskriftsakronym: J NON-CRYST SOLIDS
Volym: 357
Nummer: 21
Artikelns första sida, sidnummer: 3623
Artikelns sista sida, sidnummer: 3630
Antal sidor: 8
ISSN: 0022-3093


Abstrakt

This work studied the properties of glasses with the molar compn. 63.8SiO2-​(11.6-​x)​Na2O-​(0.7 + x)​B2O3-​19.2CaO-​3MgO-​1.5Al2O3-​0.2P2O5,​ in which x = 0, 1, 2, 3. These glasses are of interest for the development of slowly dissolving fibers to be incorporated in composites for medical applications. The thermal properties were recorded using hot stage microscopy, DTA, and heat treatments in the range of 800°-​1000 °C. The glass crystn. behavior was detd. based on calcd. values of the activation energy of crystn. and the Johnson-​Mehl-​Avrami exponent. The structural units in the glass network were identified using IR spectroscopy. Finally, in vitro dissoln. was tested in SBF soln.

The addn. of B2O3 increased the glass transition temp. and reduced the working temp. When heat treated at 900 °C, the glass with the smallest amt. of B2O3 formed two cryst. phases: magnesium silicate MgSiO3 and wollastonite CaSiO3. In the other compns., only CaSiO3 was obsd. after heat treatment at 950 °C. All the glasses crystd. preferentially from the surface. Changes in the liquidus and crystn. temps. were related to changes in the glass structure. The formation of [BO3] units led to glasses with improved resistance to crystn. and decreased liquidus temp. In the glasses with 2.7 and 3.7 mol​% B2O3, [BO3] units were transformed into [BO4] units. The formation of [BO4] led to an increase in fragility and a decrease in resistance to crystn. All the glasses dissolved slowly in simulated body fluid.


Nyckelord

Bioresorbable glasses, Silica-based glasses, thermal and structural properties

Senast uppdaterad 2019-09-12 vid 03:00