Abstract
In this study, conventional restorative glass ionomer cement (GIC) was modified by embedding it with mechanically processed cellulose fibers. Two concentrations of fibers were weighed and agglutinated into the GIC during manipulation, yielding Experimental Groups 2 (G2; 3.62 wt% of fibers) and 3 (G3; 7.24 wt% of fibers), which were compared against a control group containing no fibers (G1). The compressive strengths and elastic modulus of the three groups, and their diametral tensile strengths and stiffness, were evaluated on a universal test machine. The compressive and diametral tensile strengths were significantly higher in G3 than in G1. Statistically significant differences in elastic modulus were also found between G2 and G1 and between G2 and G3, whereas the stiffness significantly differed between G1 and G2. The materials were then characterized by scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDS). Heterogeneously shaped particles were found on the G2 and G3 surfaces, and the cement matrices were randomly interspersed with long intermingled fibers. The EDS spectra of the composites revealed the elemental compositions of the precursor materials. The physically processed cellulosic fibers (especially at the higher concentration) increased the compressive and diametral tensile strengths of the GIC, and demonstrated acceptable elastic modulus and stiffness.
Highlights
As a major constituent of plant cell walls, cellulose is responsible for the mechanical integrity and supporting structures of plants, and is widely exploited in industry.[1]
We evaluate the parameters of the modified glass ionomer cement (GIC), namely, the compressive strength, elastic modulus, and diametral tensile strength and stiffness, and characterize the materials by scanning electron microscopy and energy dispersive X-ray spectroscopy
In the compressive and diametral tensile strength tests, G1 was statistically different from Groups 2 (G2) and G3
Summary
As a major constituent of plant cell walls, cellulose is responsible for the mechanical integrity and supporting structures of plants, and is widely exploited in industry.[1] At present, wood fibers are extensively researched for end-use applications such as composite reinforcements, and as raw materials for bioenergy and biochemical production.[2,3,4] Cellulosic fibers have been shown to increase the mechanical strength and elastic modulus of cement matrices.[5,6]. Conventional glass ionomer cement (GIC), a restorative material widely used in dental clinics, presents innumerable advantages. On account of its anti-cariogenic nature, GIC helps to remineralize the affected dentin remnant and to control caries recurrence. GIC is biocompatible with tooth tissue; in particular, the ionomer cement bond minimizes microleakage at the tooth/restoration interface, Braz Oral Res [online]. GIC is biocompatible with tooth tissue; in particular, the ionomer cement bond minimizes microleakage at the tooth/restoration interface, Braz Oral Res [online]. 2015;29(1):[1,2,3,4,5,6,7,8]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
