Litcius/Paper detail

Bridging the Gap: Integrating 3D Bioprinting and Microfluidics for Advanced Multi-Organ Models in Biomedical Research

Marco De Spirito, Valentina Palmieri, Giordano Perini, Massimiliano Papi

2024Bioengineering33 citationsDOIOpen Access PDF

Abstract

Recent advancements in 3D bioprinting and microfluidic lab-on-chip systems offer promising solutions to the limitations of traditional animal models in biomedical research. Three-dimensional bioprinting enables the creation of complex, patient-specific tissue models that mimic human physiology more accurately than animal models. These 3D bioprinted tissues, when integrated with microfluidic systems, can replicate the dynamic environment of the human body, allowing for the development of multi-organ models. This integration facilitates more precise drug screening and personalized therapy development by simulating interactions between different organ systems. Such innovations not only improve predictive accuracy but also address ethical concerns associated with animal testing, aligning with the three Rs principle. Future directions include enhancing bioprinting resolution, developing advanced bioinks, and incorporating AI for optimized system design. These technologies hold the potential to revolutionize drug development, regenerative medicine, and disease modeling, leading to more effective, personalized, and humane treatments.

Topics & Concepts

Computer science3D bioprintingPersonalized medicineMicrofluidicsDrug developmentPrecision medicineBridging (networking)Preclinical testingSystems engineeringNanotechnologyBioinformaticsEngineeringTissue engineeringMedical physicsBiomedical engineeringMedicineDrugBiologyPsychiatryComputer networkPathologyMaterials science3D Printing in Biomedical ResearchInnovative Microfluidic and Catalytic Techniques InnovationAdditive Manufacturing and 3D Printing Technologies