Project Abstract

Abstract
Next-Generation Sequencing (NGS) has revolutionized the field of medical genetics by enabling rapid and cost-effective analysis of the entire human genome. This research project aims to explore the implementation of NGS in the diagnosis of genetic disorders, focusing on its potential benefits and challenges. The study begins with a comprehensive review of the background of NGS technology in medical laboratory science, highlighting its significance in improving diagnostic accuracy and patient outcomes. The problem statement revolves around the limitations of traditional genetic testing methods, such as Sanger sequencing, which are time-consuming, costly, and often only target specific genetic regions. The objective of this study is to evaluate how NGS can address these limitations and enhance the efficiency and accuracy of genetic disorder diagnosis. The research methodology includes a systematic literature review of ten key studies on the applications of NGS in genetic disorder diagnosis. The review covers various genetic disorders, including rare diseases and complex conditions, to provide a broad overview of NGS capabilities. Additionally, the methodology section discusses the technical aspects of NGS implementation, such as sample preparation, sequencing platforms, bioinformatics analysis, and interpretation of results. The findings from the literature review reveal that NGS offers numerous advantages over traditional genetic testing methods, including higher throughput, faster turnaround time, and the ability to detect a wide range of genetic variations. However, challenges such as data interpretation, variant classification, and cost remain significant barriers to widespread adoption of NGS in clinical practice. The discussion of findings delves into the implications of NGS implementation for medical laboratory scientists, healthcare providers, and patients. It explores the potential impact on diagnostic workflows, genetic counseling, treatment decisions, and the overall healthcare system. The limitations of NGS technology, such as the need for specialized training and infrastructure, are also considered. In conclusion, the research project underscores the transformative potential of NGS in the diagnosis of genetic disorders and calls for further research to address current challenges and maximize the benefits of this innovative technology. By embracing NGS as a powerful tool in medical genetics, healthcare professionals can enhance precision medicine approaches and improve patient care outcomes in the era of personalized healthcare.

Project Overview