Simpson Sydney, McMinn Chelsey, Van Mondfrans Sherry M, Hendry Jackson, Ronayne Sean, Dewhurst Stephen, Feng Changyong, Bal B Sonny, Bock Ryan M, McEntire Bryan J
QuidelOrtho Corporation, 100 Indigo Creek Dr., Rochester, NY 14620 USA.
SINTX Technologies, Inc., Salt Lake City, UT 84119 USA.
Biomed Mater Devices. 2022 Jul 20:1-14. doi: 10.1007/s44174-022-00001-8.
Medical-grade masks and N95 respirators containing non-woven fibers are designed to prevent the spread of airborne diseases. While they effectively trap respiratory droplets and aerosols, they cannot lyse entrapped pathogens. Embedded antimicrobial agents such as silver, copper, zinc, iodine, peptides, quaternary ammonium salts, or nanoparticles have been used to overcome this limitation. However, their effectiveness remains debatable because these materials can be toxins, allergens, irritants, and environmental hazards. Recently, silicon nitride (SiN) was found to be a potent antipathogenic compound, and it may be an ideal agent for masks. In powder or solid form, it is highly effective in inactivating bacteria, fungi, and viruses while leaving mammalian tissue unaffected. The purpose of this study was to serially assess the antiviral efficacy of SiN against SARS-CoV-2 using powders, solids, and embedded nonwoven fabrics. SiN powders and solids were prepared using conventional ceramic processing. The "pad-dry-cure" method was used to embed SiN particles into polypropylene fibers. Fabric testing was subsequently conducted using industrial standards-ISO 18184 for antiviral effectiveness, ASTM F2299 and EN 13274-7 for filtration efficiency, EN 14683 for differential pressure drop, and ISO 18562-2 for particle shedding. A modification of ISO 18562-3 was also employed to detect ammonia release from the fabric. Antiviral effectiveness for SiN powders, solids, and embedded fabrics were 99.99% at ≤ 5 min, ~ 93% in 24 h, and 87% to 92% in 120 min, respectively. Results of the standard mask tests were generally within prescribed safety limits. Further process optimization may lead to commercial SiN-based masks that not only "catch" but also "kill" pathogenic microbes.
含有非织造纤维的医用级口罩和N95呼吸器旨在防止空气传播疾病的传播。虽然它们能有效捕获呼吸道飞沫和气溶胶,但无法裂解捕获的病原体。嵌入银、铜、锌、碘、肽、季铵盐或纳米颗粒等抗菌剂已被用于克服这一局限性。然而,它们的有效性仍存在争议,因为这些材料可能是毒素、过敏原、刺激物和环境危害物。最近,氮化硅(SiN)被发现是一种有效的抗病原体化合物,它可能是口罩的理想试剂。以粉末或固体形式存在时,它在灭活细菌、真菌和病毒方面非常有效,同时不会影响哺乳动物组织。本研究的目的是使用粉末、固体和嵌入的非织造织物连续评估SiN对严重急性呼吸综合征冠状病毒2(SARS-CoV-2)的抗病毒效果。SiN粉末和固体采用传统陶瓷工艺制备。采用“浸轧-烘干-焙烘”法将SiN颗粒嵌入聚丙烯纤维中。随后使用工业标准进行织物测试——抗病毒效果采用ISO 18184,过滤效率采用ASTM F2299和EN 13274-7,压差采用EN 14683,颗粒脱落采用ISO 18562-2。还采用了ISO 18562-3的修改版来检测织物中的氨释放。SiN粉末、固体和嵌入织物的抗病毒效果分别在≤5分钟时为99.99%、24小时内约为93%、120分钟内为87%至92%。标准口罩测试结果通常在规定的安全限度内。进一步的工艺优化可能会导致商业化的基于SiN的口罩,这种口罩不仅能“捕获”而且能“杀死”致病微生物。
