US university trying to 'print' human organs using AI, says study offers hopeful glimpse into future

Artificial intelligence (AI) continues to push the boundaries of what’s possible, from boosting workplace productivity to helping detect cancer early. Now, researchers at Washington State University (WSU) are exploring a groundbreaking application of AI: the 3D printing of human organs.

While the concept may seem futuristic, recent developments suggest it could one day become a reality. The team at WSU has developed a technique using an AI method called Bayesian Optimization, which has the potential to significantly improve the speed and precision of 3D printing complex, lifelike human organs.

The findings, published in the journal Advanced Materials Technologies, highlight how this AI-driven approach could revolutionise the use of 3D printing not just for creating artificial organs, but also for producing intricate designs in fields like electronics and wearable biosensors.

The major advancement here is that the AI algorithm can now be utilised to efficiently 3D print even the most complex structures, offering a glimpse into a future where creating functional human organs in a lab might be possible.

In a detailed report by WSU Insider, it was noted that as part of the study, the AI algorithm was trained to identify and print the most accurate versions of kidney and prostate organ models. Impressively, the model managed to produce 60 progressively refined versions of these organs. The AI approach was said to optimize the process by saving time, reducing costs, and minimising labour, marking a significant improvement over traditional methods.

3D printing has been gaining traction in recent years, but it comes with challenges, particularly when it comes to setting up the correct parameters for complex printing tasks. Engineers must consider factors like materials, printer configuration, and nozzle dispensing pressure, making the process intricate and time-consuming.

The AI model developed at WSU addresses these challenges by balancing geometric precision, density, and printing time to produce organ models that are both realistic in appearance and function.

The potential applications of this technology extend beyond medicine. If realized, it could have implications for industries such as computer science, aviation, and automotive engineering.

The 3D-printed organ models could be used to train surgeons or evaluate implant devices, but to do so effectively, these models would need to replicate the mechanical and physical properties of real human organs, including the intricate networks of veins, arteries, and other channels.

In the early stages of their work, the WSU researchers trained the AI to print a surgical rehearsal model of a prostate. The success of this model demonstrated the algorithm’s flexibility; with only minor adjustments, it was adapted to create a kidney model.

This adaptability suggests that the AI technique could be broadly applicable, making it a powerful tool in the ongoing effort to advance 3D printing technology in both medical and industrial contexts.