Dept. of Materials Science and Engineering, University of Illinois Urbana-Champaign, Urbana, IL, 61801, USA.
Carl R. Woese Institute for Genomic Biology, University of Illinois Urbana-Champaign, Urbana, IL, 61801, USA.
Biomaterials. 2023 Mar;294:122015. doi: 10.1016/j.biomaterials.2023.122015. Epub 2023 Jan 19.
The design of biomaterials to regenerate bone is likely to increasingly require modifications that reduce bacterial attachment and biofilm formation as infection during wound regeneration can significantly impede tissue repair and typically requires surgical intervention to restart the healing process. Further, much research on infection prevention in bone biomaterials has focused on modeling of non-resorbable metal alloy materials, whereas an expanding direction of bone regeneration has focused on development of bioresorbable materials. This represents a need for the prevention and understanding of infection in resorbable biomaterials. Here, we investigate the ability of a mineralized collagen biomaterial to natively resist infection and examine how the addition of manuka honey, previously identified as an antimicrobial agent, affects gram positive and negative bacterial colonization and mesenchymal stem cell osteogenesis and vasculature formation. We incorporate manuka honey into these scaffolds via either direct fabrication into the scaffold microarchitecture or via soaking the scaffold in a solution of manuka honey after fabrication. Direct incorporation results in a change in the surface characteristics and porosity of mineralized collagen scaffolds. Soaking scaffolds in honey concentrations higher than 10% had significant negative effects on mesenchymal stem cell metabolic activity. Soaking or incorporating 5% honey had no impact on endothelial cell tube formation. Although solutions of 5% honey reduced metabolic activity of mesenchymal stem cells, MSC-seeded scaffolds displayed increased calcium and phosphorous mineral formation, osteoprotegerin release, and alkaline phosphatase activity. Bacteria cultured on mineralized collagen scaffolds demonstrated surfaces covered in bacteria and no method of preventing infection, and using 10 times the minimal inhibitory concentration of antibiotics did not completely kill bacteria within the mineralized collagen scaffolds, indicating bioresorbable scaffold materials may act to shield bacteria from antibiotics. The addition of 5% manuka honey to scaffolds was not sufficient to prevent P. aeruginosa attachment or consistently reduce the activity of methicillin resistant staphylococcus aureus, and concentrations above 7% manuka honey are likely necessary to impact MRSA. Together, our results suggest bioresorbable scaffolds may create an environment conducive to bacterial growth, and potential trade-offs exist for the incorporation of low levels of honey in scaffolds to increase osteogenic potential of osteoprogenitors while high-levels of honey may be sufficient to reduce gram positive or negative bacteria activity but at the cost of reduced osteogenesis.
设计用于再生骨骼的生物材料可能需要越来越多的修改,以减少细菌附着和生物膜形成,因为在伤口再生过程中发生感染会严重阻碍组织修复,通常需要手术干预才能重新开始愈合过程。此外,关于骨生物材料感染预防的大量研究集中在不可吸收金属合金材料的建模上,而骨再生的一个扩展方向集中在可吸收材料的开发上。这就需要预防和了解可吸收生物材料的感染。在这里,我们研究了矿化胶原生物材料天然抵抗感染的能力,并研究了添加之前被确定为抗菌剂的麦卢卡蜂蜜如何影响革兰氏阳性和革兰氏阴性细菌的定植以及间充质干细胞成骨和血管形成。我们通过直接将麦卢卡蜂蜜掺入支架的微结构中或在支架制造后将支架浸泡在麦卢卡蜂蜜溶液中来将麦卢卡蜂蜜掺入这些支架中。直接掺入会改变矿化胶原支架的表面特性和孔隙率。将支架浸泡在浓度高于 10%的蜂蜜中会对间充质干细胞的代谢活性产生显著的负面影响。将支架浸泡在 5%的蜂蜜中或不影响内皮细胞管形成。尽管 5%的蜂蜜溶液降低了间充质干细胞的代谢活性,但 MSC 接种的支架显示出增加的钙和磷矿化、骨保护素释放和碱性磷酸酶活性。在矿化胶原支架上培养的细菌显示出被细菌覆盖的表面,并且没有任何方法可以预防感染,并且使用抗生素的最小抑菌浓度的 10 倍也不能完全杀死矿化胶原支架内的细菌,这表明可吸收的支架材料可能会阻止细菌对抗生素的吸收。向支架中添加 5%的麦卢卡蜂蜜不足以防止铜绿假单胞菌附着或始终降低耐甲氧西林金黄色葡萄球菌的活性,并且需要高于 7%的麦卢卡蜂蜜浓度才能影响耐甲氧西林金黄色葡萄球菌。总之,我们的结果表明,可吸收支架可能会创造出有利于细菌生长的环境,并且在支架中掺入低水平的蜂蜜以增加成骨前体细胞的成骨潜力与高水平的蜂蜜之间可能存在潜在的权衡,因为高水平的蜂蜜可能足以降低革兰氏阳性或革兰氏阴性细菌的活性,但代价是成骨减少。
