Abstract
Abstract The biocompatibility of photosensitive glasses allows various biomedical applications; one is the field of tissue engineering and more precisely microengineered tissue-on-a-chip platforms to study the tissue microenvironment and disease modelling. Three dimensional architectures of adapted components are required for modern materials. A photosensitive lithiumalumosilicate glass FS21 was investigated regarding the interaction with a Ti:Sapphire laser systemto build three dimensional buried channels inside the glass. Femtosecond laser radiation with a wavelength of 800 nm and pulse duration of 140 fs was used to modify the glass structure. Subsurface channel geometries were achieved by a subsequent thermal treatment and were formed into capillaries using wet chemical etching of the exposed and crystallised channels. Contrary to ultraviolet (UV) exposure, spectral optical investigations showed that fs laser exposure caused various radiation induced defects in the base glass coupled with the generation of photoelectrons for the photochemical modification of silver ions. We observed an outgassing of different species coming from raw materials of the original glass batch during the glass crystallisation process. Etch rate ratios differ between 1:25 and 1:45 and are dependent on: stoichiometric deviation between surface and bulk, crystal size and distribution and exchange of the etching agent in narrow capillaries.
Highlights
The biocompatibility of photosensitive glasses allows various biomedical applications; one is the field of tissue engineering and more precisely microengineered tissue-on-a-chip platforms to study the tissue microenvironment and disease modelling
Similar to numerous investigations of the photoform process regarding the commercial photosensitive glass Foturan [16, 24,25,26], an established spectrum of methods was applied to evaluate the photoreaction mechanism of the fs laser exposure using the wavelength of 800 nm
We investigated a photosensitive lithiumalumosilicate glass FS21 doped with CeO2, Ag2O, SnO, Sb3O5 regarding the sensitivity to fs laser radiation in comparison to UV lamp exposure in a mask aligner
Summary
Abstract: The biocompatibility of photosensitive glasses allows various biomedical applications; one is the field of tissue engineering and more precisely microengineered tissue-on-a-chip platforms to study the tissue microenvironment and disease modelling. The influence of cw NIR laser irradiation on the thermal induced crystallization of lithium disilicate in base glasses with variable CuO contents is discussed in [12]. In addition to reactions (1) and (2) intensive radiation can induce further reactions inside the glass structure by breaking bonds in the base glass composition [15] In these cases, the photoionisation of Ce3+ should only be considered as a minor process in the generation of photoelectrons. It is necessary to study the following process steps: irradiation treatment of the glass, thermal treatment for glass crystallization by growing lithium metasilicate in exposed areas and wet chemical etching of crystallised parts using diluted hydrofluoric acid dependent on parameter variations in the exposure process
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