Calvo-Guirado José Luis, Ballester-Montilla Alvaro, N De Aza Piedad, Fernández-Domínguez Manuel, Alexandre Gehrke Sergio, Cegarra-Del Pino Pilar, Mahesh Lanka, Pelegrine André Antonio, Aragoneses Juan Manuel, Maté-Sánchez de Val José
Department of Oral and Implant Surgery. Faculty of Health Sciences. Universidad Católica San Antonio de Murcia, 30002 Murcia, Spain.
International Dentistry Research Cathedra. Universidad Católica San Antonio de Murcia.
Materials (Basel). 2019 Jan 25;12(3):380. doi: 10.3390/ma12030380.
The aim of the study was to evaluate the chemical composition of crushed, extracted human teeth and the quantity of biomaterial that can be obtained from this process. A total of 100 human teeth, extracted due to trauma, decay, or periodontal disease, were analyzed. After extraction, all the teeth were classified, measured, and weighed on a microscale. The human teeth were crushed immediately using the Smart Dentin Grinder machine (KometaBio Inc., Cresskill, NJ, USA), a device specially designed for this procedure. The human tooth particles obtained were of 300⁻1200 microns, obtained by sieving through a special sorting filter, which divided the material into two compartments. The crushed teeth were weighed on a microscale, and scanning electron microscopy (SEM) evaluation was performed. After processing, 0.25 gr of human teeth produced 1.0 cc of biomaterial. Significant differences in tooth weight were found between the first and second upper molars compared with the lower molars. The chemical composition of the particulate was clearly similar to natural bone. Scanning electron microscopy⁻energy dispersive X-ray (SEM⁻EDX) analysis of the tooth particles obtained mean results of Ca% 23.42 0.34 and P% 9.51 0.11. Pore size distribution curves expressed the interparticle pore range as one small peak at 0.0053 µm. This result is in accordance with helium gas pycnometer findings; the augmented porosity corresponded to interparticle spaces and only 2.533% corresponded to intraparticle porosity. Autogenous tooth particulate biomaterial made from human extracted teeth may be considered a potential material for bone regeneration due to its chemical composition and the quantity obtained. After grinding the teeth, the resulting material increases in quantity by up to three times its original volume, such that two extracted mandibular lateral incisors teeth will provide a sufficient amount of material to fill four empty mandibular alveoli. The tooth particles present intra and extra pores up to 44.48% after pycnometer evaluation in order to increase the blood supply and support slow resorption of the grafted material, which supports healing and replacement resorption to achieve lamellar bone. After SEM⁻EDX evaluation, it appears that calcium and phosphates are still present within the collagen components even after the particle cleaning procedures that are conducted before use.
本研究的目的是评估粉碎、提取后的人牙的化学成分,以及通过该过程可获得的生物材料的数量。共分析了100颗因外伤、龋齿或牙周病而拔除的人牙。拔牙后,对所有牙齿进行分类、测量并在微观尺度上称重。使用智能牙本质研磨机(美国新泽西州克雷斯基尔的KometaBio公司)立即对人牙进行粉碎,该设备是专门为此程序设计的。通过特殊的分选过滤器筛分得到的人牙颗粒大小为300⁻1200微米,该过滤器将材料分为两个隔室。对粉碎后的牙齿进行微观称重,并进行扫描电子显微镜(SEM)评估。处理后,0.25克人牙产生1.0立方厘米的生物材料。与下磨牙相比,第一和第二上磨牙的牙齿重量存在显著差异。颗粒的化学成分明显与天然骨相似。对获得的牙齿颗粒进行扫描电子显微镜⁻能量色散X射线(SEM⁻EDX)分析,钙含量的平均结果为23.42±0.34%,磷含量为9.51±0.11%。孔径分布曲线显示颗粒间孔隙范围为一个位于0.0053 µm的小峰。该结果与氦气比重计的结果一致;增加的孔隙率对应于颗粒间空间,仅2.533%对应于颗粒内孔隙率。由于其化学成分和获得的数量,由人拔除的牙齿制成的自体牙颗粒生物材料可被视为骨再生的潜在材料。牙齿研磨后,所得材料的体积增加至其原始体积的三倍,因此两颗拔除的下颌侧切牙将提供足够的材料来填充四个空的下颌牙槽。比重计评估后,牙齿颗粒的内部和外部孔隙率高达44.48%,以增加血液供应并支持移植材料的缓慢吸收,从而支持愈合和替代吸收以形成板层骨。经过SEM⁻EDX评估,即使在使用前进行了颗粒清洁程序,似乎钙和磷酸盐仍存在于胶原蛋白成分中。
