Thesis Abstract

Abstract
The field of medical laboratory science has seen significant advancements in diagnostic technologies, with Next-Generation Sequencing (NGS) emerging as a powerful tool for the detection and characterization of infectious diseases. This thesis explores the application of NGS technology in enhancing the diagnosis of infectious diseases, with a focus on its potential to revolutionize current laboratory practices. The study delves into the background of NGS technology, highlighting its capabilities and advantages over traditional diagnostic methods. The problem statement addresses the limitations of existing diagnostic techniques in accurately and rapidly identifying infectious agents, leading to delays in treatment and potential public health risks. The main objective of this research is to evaluate the effectiveness of NGS in diagnosing infectious diseases and to propose recommendations for its implementation in routine laboratory settings. The scope of the study encompasses a comprehensive review of literature on NGS technology and its applications in infectious disease diagnosis. Methodologies employed include data collection, analysis, and interpretation of findings from relevant studies and case reports. The research methodology section details the approach taken in data collection, sample processing, sequencing, bioinformatics analysis, and validation of results. The discussion of findings presents an in-depth analysis of the benefits and challenges associated with the use of NGS in infectious disease diagnosis. Key findings include the high sensitivity and specificity of NGS in detecting a wide range of pathogens, its ability to identify drug resistance markers, and the potential for rapid turnaround time. In conclusion, this thesis underscores the significance of incorporating NGS technology into routine laboratory practices for the diagnosis of infectious diseases. The study highlights the impact of NGS on improving patient outcomes, guiding appropriate treatment strategies, and enhancing surveillance and outbreak investigations. Recommendations for future research and the widespread adoption of NGS in clinical laboratories are discussed. Overall, this thesis provides valuable insights into the transformative potential of NGS technology in revolutionizing the field of medical laboratory science and advancing the diagnosis of infectious diseases.

Thesis Overview

The project titled "Application of Next-Generation Sequencing Technology in the Diagnosis of Infectious Diseases" aims to explore the potential of next-generation sequencing (NGS) technology in revolutionizing the field of medical diagnostics, particularly in the realm of infectious diseases. In recent years, NGS has emerged as a powerful tool in genomics, offering high-throughput sequencing capabilities that allow for the rapid and comprehensive analysis of genetic material. This technology has the potential to transform the way infectious diseases are diagnosed, providing a more accurate, timely, and personalized approach to patient care. The research will begin with an introduction to the background of NGS technology and its applications in the field of medical laboratory science. The problem statement will highlight the current challenges and limitations in traditional diagnostic methods for infectious diseases, emphasizing the need for more advanced and efficient techniques. The objectives of the study will focus on assessing the feasibility and effectiveness of NGS technology in diagnosing infectious diseases, as well as exploring its potential benefits in terms of accuracy, speed, and cost-effectiveness. The study will also address the limitations and challenges associated with implementing NGS in clinical settings, such as data analysis, interpretation, and standardization. The scope of the study will encompass a review of relevant literature on NGS technology and its applications in infectious disease diagnostics. The significance of the study lies in its potential to contribute to the advancement of medical laboratory science, offering insights into how NGS can improve patient outcomes and public health. The structure of the thesis will be outlined, detailing the chapters and sub-chapters that will guide the research process. Definitions of key terms related to NGS technology and infectious diseases will be provided to establish a common understanding of the subject matter. Overall, this research overview sets the stage for a comprehensive investigation into the application of NGS technology in the diagnosis of infectious diseases, with the ultimate goal of advancing medical diagnostics and improving patient care.