Abstract
The use of naturally occurring materials in biomedicine has been increasingly attracting the researchers’ interest and, in this regard, gum tragacanth (GT) is recently showing great promise as a therapeutic substance in tissue engineering and regenerative medicine. As a polysaccharide, GT can be easily extracted from the stems and branches of various species of Astragalus. This anionic polymer is known to be a biodegradable, non-allergenic, non-toxic, and non-carcinogenic material. The stability against microbial, heat and acid degradation has made GT an attractive material not only in industrial settings (e.g., food packaging) but also in biomedical approaches (e.g., drug delivery). Over time, GT has been shown to be a useful reagent in the formation and stabilization of metal nanoparticles in the context of green chemistry. With the advent of tissue engineering, GT has also been utilized for the fabrication of three-dimensional (3D) scaffolds applied for both hard and soft tissue healing strategies. However, more research is needed for defining GT applicability in the future of biomedical engineering. On this object, the present review aims to provide a state-of-the-art overview of GT in biomedicine and tries to open new horizons in the field based on its inherent characteristics.
Highlights
Gums are known to be pathological products generated after plant injuries or due to unfavorable conditions through the breakdown of cell walls
Iranian tragacanth ribbons are sorted into five grades, while flakes are provided in seven different grades [3,4]
The chemical composition of the commercial gum tragacanth (GT) attained from different species shows significant differences, which are directly resulted from seasonal and geographical variations [4]
Summary
Gums are known to be pathological products generated after plant injuries or due to unfavorable conditions (e.g., drought) through the breakdown of cell walls (extracellular formation; gummosis). We aim to highlight the biological benefits of GT in biomedicine (see Figure 1) and critically analyze the limitations on the way of the extensive usage of this natural biomaterial in tissue engineering and regenerative medicine applications. For this purpose, physico-chemical and biological properties of GT are first summarized, and Molecules 202t1h, 2e6,nx FtOhRePErEeRsRuEVltIEsWof in vitro and in vivo evaluations of GT, either alone or in3coof 1m8 bination with other materials, will be discussed. This natural substance is being applied for a broad range of applica2ti.oRnesse,afrrcohmMdetrhuogdodloegliyvery strategies to hard and soft tissue engineering. Scientific and author names of plant species are reported according to the most recent monograph of the genus [18]
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