Metagenomics in diagnosis and improved targeted treatment of UTI

INTRODUCTION: The genomic revolution has transformed our understanding of urinary tract infection. There has been a paradigm shift from the dogmatic statement that urine is sterile in healthy people, as we are becoming forever more familiar with the knowledge that bacterial communities exist within the urinary tracts of healthy people. Metagenomics can investigate the broad populations of microbial communities, analysing all the DNA present within a sample, providing comprehensive data regarding the state of the microenvironment of a patient's urinary tract. This permits medical practitioners to more accurately target organisms that may be responsible for disease-a form of 'precision medicine'. METHODS AND RESULTS: This paper is derived from an extensive review and analysis of the available literature on the topic of metagenomic sequencing in urological science, using the PubMed search engine. The search yielded a total of 406 results, and manual selection of appropriate papers was subsequently performed. Only one randomised clinical trial comparing metagenomic sequencing to standard culture and sensitivity in the arena of urinary tract infection was found. CONCLUSION: Out of this process, this paper explores the limitations of traditional methods of culture and sensitivity and delves into the recent studies involving new high-throughput genomic technologies in urological basic and clinical research, demonstrating the advances made in the urinary microbiome in its entire spectrum of pathogens and the first attempts of clinical implementation in several areas of urology. Finally, this paper discusses the challenges that must be overcome for such technology to become widely used in clinical practice

An Implementation Of Next Generation Sequencing For Prevention And Diagnosis Of Urinary Tract Infection In Urology

Introduction: The changing face of current infection phenotypes from planktonic to biofilm type has been developed implicating bacterial biofilms in recurrent infection. To date, no specific medical treatment exists to specifically target biofilms in the human host. Similarly, the identification of a biofilm has relied upon the analysis of tissue samples with electron microscopy or DNA identification with polymerase chain reaction (PCR) and sequencing. Standard culture and sensitivity test is not able to detect a presence of biofilms. Materials and methods: Two types of molecular microbial diagnostic testing levels are performed as noted below. In both types of analysis, the microbial DNA is extracted from the patient\u27s sample. The patient report contains information about the pathogenic bacterial and fungal microorganisms detected, bacterial load and resistance genes to different antibiotics. Once the bacteria have been identified antibiotic recommendations are made based on research confirming the effectiveness of treatment. The technique was tested in 112 patients in different areas of urology for prevention and treatment purpose. Results: The clinical application of next generation sequence in different clinical phase I-II trials (acute cystitis in 56 patients, rectal swabs before transrectal prostate biopsy in 32 men, neurogenic bladder in 13 patients, chronic bacterial prostatitis in 17 men) demonstrated that this novel approach extends our knowledge about the microbiome of the urogenital tract in both men and women. DNA sequence has a high sensitivity to detect a bacterial and fungal association with resistant genes to antibiotics revealed allowing to implement a targeted and individual prevention and treatment of urinary tract infection (UTI) with improved efficacy compared to standard culture and sensitivity technique. Conclusion: The next generation DNA sequence technology enables the discovery of new concepts regarding the role of microorganisms in diseases of the urinary tract with an individualized approach for a more accurate diagnosis, prevention, prophylaxis and treatment of UTI