Abstract
INTRODUCTION: A new era of regenerative medicine has been ushered in by the combination of tissue engineering and genetic engineering, offering unprecedented opportunities to address the growing demand for functional tissue replacements. This narrative review explores cutting-edge approaches in cell manipulation-based tissue engineering through the lens of genetic engineering, highlighting the transformative potential of this synergy. METHODS: We critically examine the application of advanced genetic engineering techniques, including CRISPR-Cas9, TALENs, and synthetic biology, in modifying cellular behaviors and functions for tissue engineering. The review encompasses a diverse range of engineered tissues, from cartilage and bone to cardiac, neural, skin, and vascular constructs, elucidating how genetic manipulation enhances their functionality and physiological relevance. We further investigate the integration of these genetic approaches with emerging technologies such as 3D-bioprinting, microfluidics, and smart biomaterials, which collectively expand the horizons of complex tissue fabrication. RESULTS: The review delves into pioneering trends, including in vivo genetic engineering for tissue regeneration and the development of patient-specific engineered tissues, discussing their implications for personalized medicine. We address the field's challenges, including long-term genetic stability, scalability, and off-target effects, while also considering the ethical implications and evolving regulatory landscape of genetically engineered tissues. Emerging technologies in genetic engineering, including base editing and synthetic genetic circuits, have been explored for their potential to create "smart" tissues capable of dynamic environmental responses. The review also highlights the synergistic potential of combining genetic engineering with stem cell technologies to enhance tissue functionality and immunological compatibility. CONCLUSION: This comprehensive review concludes by underscoring the transformative impact of genetic engineering on cell manipulation-based tissue engineering. While significant challenges persist, the rapid advancements in this field herald a future where genetically tailored, functional tissue constructs could revolutionize regenerative medicine, offering new hope for addressing critical unmet medical needs.