Gioitta Iachino Salvatore, Scaggiante Federica, Mazzarisi Claudia, Schaller Christian
Department of Orthopaedics and Traumatology, Hospital of Brixen, Lehrkrankenhaus der Paracelsus Medizinischen Privatuniversität, Südtiroler Sanitätsbetrieb (SABES-ASDAA), 39042 Brixen, Italy.
Laboratory of Clinical Pathology, Hospital of Brixen, Lehrkrankenhaus der Paracelsus Medizinischen Privatuniversität, Südtiroler Sanitätsbetrieb (SABES-ASDAA), 39042 Brixen, Italy.
Antibiotics (Basel). 2024 Oct 1;13(10):931. doi: 10.3390/antibiotics13100931.
Periprosthetic joint infections are still a challenge in orthopedics and traumatology. Nowadays, genomics comes to the aid of diagnosis and treatment, in addition to traditional methods. Recently, a key role of the intestinal microbiota has been postulated, and great efforts are aimed at discovering its interconnection, which shows to be at different levels. Firstly, the gut microbiome influences the immune system through the gut-associated lymphoid tissue (GALT). A balanced microbiome promotes a strong immune response, which is essential to prevent all local and systemic infections, including PJI. Thus, a dysbiosis, i.e., the disruption of this system, leads to an imbalance between the various strains of microorganisms co-existing in the gut microbiome, which can result in a weakened immune system, increasing susceptibility to infections, including PJI. Additionally, the dysbiosis can result in the production of pro-inflammatory mediators that enter the systemic circulation, creating a state of chronic inflammation that can compromise the immune system's ability to fend off infections. Furthermore, the microbiome maintains the integrity of the gut barrier, preventing the translocation of harmful bacteria and endotoxins into the bloodstream; dysbiosis can compromise this protective "wall". In addition, the gut microbiome may harbor antibiotic-resistance genes; during antibiotic treatment for other infections or prophylaxis, these genes may be transferred to pathogenic bacteria, making the treatment of PJI more difficult. In this complex landscape, next-generation sequencing (NGS) technology can play a key role; indeed, it has revolutionized the study of the microbiome, allowing for detailed and comprehensive analysis of microbial communities. It offers insights into the functional potential and metabolic capabilities of the microbiome, studies the collective genome of the microbiome directly from environmental samples sequencing DNA without isolating individual organisms, analyzes the RNA transcripts to understand gene expression and functional activity of the microbiome, analyzes the RNA transcripts to understand gene expression and functional activity of the microbiome, investigates the metabolites produced by the microbiome and studies the entire set of proteins produced by the microbiome. NGS technology, the study of the micromyoma and its implications in the field of orthopedic trauma are innovative topics on which few publications are yet to be found in the international scientific literature. The costs are still high, the focus of research is maximum, and it will certainly change our approach to infections. Our study is an up-to-date review of the hot topic application of NGS in the study and investigation of periprosthetic infections and the microbiome.
人工关节周围感染仍是骨科和创伤学领域的一项挑战。如今,除了传统方法外,基因组学也为诊断和治疗提供了帮助。最近,肠道微生物群的关键作用被提出,人们正致力于发现其在不同层面的相互联系。首先,肠道微生物群通过肠道相关淋巴组织(GALT)影响免疫系统。平衡的微生物群促进强大的免疫反应,这对于预防包括人工关节周围感染(PJI)在内的所有局部和全身感染至关重要。因此,生态失调,即该系统的破坏,会导致肠道微生物群中共存的各种微生物菌株之间失衡,这可能导致免疫系统减弱,增加包括PJI在内的感染易感性。此外,生态失调会导致促炎介质的产生,这些介质进入体循环,造成慢性炎症状态,可能损害免疫系统抵御感染的能力。此外,微生物群维持肠道屏障的完整性,防止有害细菌和内毒素进入血液;生态失调会损害这道保护性的“屏障”。此外,肠道微生物群可能含有抗生素抗性基因;在针对其他感染或预防进行抗生素治疗期间,这些基因可能转移到病原菌,使PJI的治疗更加困难。在这一复杂的情况下,下一代测序(NGS)技术可以发挥关键作用;事实上,它彻底改变了微生物群的研究,允许对微生物群落进行详细和全面的分析。它能深入了解微生物群的功能潜力和代谢能力,直接从对环境样本测序DNA而不分离单个生物体来研究微生物群的集体基因组,分析RNA转录本以了解微生物群的基因表达和功能活性,分析RNA转录本以了解微生物群的基因表达和功能活性,研究微生物群产生的代谢物并研究微生物群产生的全套蛋白质。NGS技术、微肌瘤的研究及其在骨科创伤领域的意义是创新课题,在国际科学文献中很少有相关出版物。成本仍然很高,研究重点极大,而且它肯定会改变我们对感染的处理方法。我们的研究是对NGS在人工关节周围感染和微生物群的研究与调查中的热点应用的最新综述。
