琼脂糖水凝胶和 LLRP 作为再矿化的辅助手段

Neco Lawrence, Hanna Passmore, Ashley Christman RDH, BS
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引用次数: 0

摘要

目的通过模拟髓质生成的初始阶段,研究琼脂糖水凝胶和amp;LRAP(富含卢西亚氨酸的髓质蛋白)作为再矿化生物模拟辅助剂的当前功效;创建新的牙齿结构。方法本综述所使用的文章均从奥古斯塔大学数据库中获取,并在过去 5 年内发表。我们排除了荟萃分析和文献综述。使用关键词:釉质再生、琼脂糖、水凝胶、釉质再矿化。结果(如适用)在这些研究中,牙齿在 3% 次氯酸钠溶液中消毒,并用磷酸盐缓冲盐水分层。然后用不同的方法将牙齿切片,并用超声波清洗。然后用 37% 的磷酸进行蚀刻并储存,以模拟持续脱矿。结果表明,所有辅助剂都能复制羟基磷灰石晶体和牙釉质结构。LRAP 溶液保持了中性的 pH 值,从而保护了磷酸盐并使其能够稳定釉质再生。6 天后,琼脂糖水凝胶可以再生出矿化组织,就像健全的牙釉质一样。结论各项研究表明,LRAP、琼脂糖水凝胶和釉质基质蛋白可以引导釉质再生。LRAP 能够影响晶体的定位和形态,因此是一种很有前景的釉质再生生物大分子。与釉质生成相比,琼脂糖水凝胶在复制健全釉质方面具有显著的效果。釉质基质蛋白可以自发地自我组装成纳米球结构,并像健全的釉质一样吸引钙离子和磷酸根离子。无论是否有私人保险,这种性质的修复工作都可能很昂贵,因此找到成本效益更高的生物仿生材料可能是有益的。需要进一步研究合成珐琅质的局限性。
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Agarose Hydrogel & LLRP As Adjuncts to Remineralization

OBJECTIVES

Examine the current efficacy of Agarose Hydrogel & LRAP (Luciene rich Amelogenin proteins) as biomimetic adjuncts to remineralization by mimicking the beginning stages of amelogenesis; creating new tooth structure.

METHODS

For this review, the articles used were accessed from the Augusta University

Database and published within the past 5 years. We excluded meta-analysis and literature reviews. Used the keywords: enamel regeneration, agarose, hydrogel, enamel remineralization.

RESULTS

(If applicable) In these studies, teeth were disinfected in a 3% sodium hypochlorite solution and layered with Saline buffered with Phosphate. The teeth were then sliced with different methods, and ultrasonically cleansed. They were then etched with 37% phosphoric acid and stored to mimic constant demineralization. All of the adjuncts were shown to have the ability to replicate Hydroxyapatite crystals and the structure of enamel. The LRAP solution maintained a neutral pH level that protects the phosphate and enables it to stabilize enamel regeneration. After 6 days, the Agarose Hydrogel can regenerate mineralized tissues like sound enamel. After being treated with enamel matrix proteins, after 24 hours, the hydroxyapatite crystals formed prismatic structures with a 5 μm diameter.

CONCLUSIONS

Each study indicates that LRAP, Agarose Hydrogel, and Enamel Matrix Proteins could direct enamel regeneration. LRAP is a promising biomolecule for enamel regeneration because of its capacity to affect crystal positioning and form. Comparatively to amelogenesis, Agarose Hydrogel has significantly promising results to replicate sound enamel. The Enamel Matrix Proteins can spontaneously self- assemble into nanosphere structures and attract calcium and phosphate ions like sound enamel.

IMPLICATIONS

Long-term clinical trials would be needed to measure risks & potential adverse effects. Restorative work of this nature may be costly with or without private insurance, it may be beneficial to find more cost- effective biomimetic materials.Treatment would happen over multiple days in private practice. Further studies would be needed to examine the limitations of how much enamel can be synthetically produced.

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