Organ chip technology is transforming modern research because it mimics personalized organ systems and will serve as an alternative to animal testing and other testing methods. The organ on a chip is the size of a coin, clear and flexible with a two-channel microfluidic chip separated by a cell-permeable membrane. The microfluidic chips mimic organ functions or states in the body. The cell-permeable membrane is thin and can be stretched by a vacuum to allow for cellular communication between microfluidic chips. A tissue-specific support layer covers the cell-permeable membrane to aid in tissue growth and maturation. Organ chips are grown in a small device that controls chip movement so it can properly demonstrate the functions of the body.
The first organ on a chip was developed in the 2000s. It was designed to model excess fluid accumulation in diseased lungs. The organ chip mimicked the airways in the lungs and even made a similar “crackle” noise, a symptom in patients with diseased lungs. Following the development of the lung chip in 2010, fifteen more chips were developed after other organs and systems in the body and can even mimic diseases and genetic disorders in the body. Beyond human systems, organ chips have been developed to model dogs, rats, and mice.
As opposed to traditional animal testing methods, organ on a chip provides information about a drug’s effect specifically on human cells. Organ on a chip technology is intended to accurately represent the body’s organs and functions on a small, simple to use device to support a faster way to test the impact of drugs and their doses on the body. The technology is capable of determining whether new drugs are safe by discovering early warning signs which helps researchers accurately understand disease effects on the body. This information and technological ability can lead to tailored treatments for individuals by providing researchers information on how specific people will respond to a drug. A “Patient-on-a-Chip” program is being developed to provide patients with tailored treatments to make care safer and more effective. Scientists collect blood or skin cell samples that are converted into special stem cells and then created into organ cells containing the person’s genetics. Scientists can test drugs on the organ chips and see how the specific person would respond before the person takes the medicine.
Since this is a novel technology, regulatory agencies can be less likely to accept the data from an organ chip and may require additional information to confirm the accuracy of the findings. However, the Food and Drug Administration (FDA) has conveyed interest in organ chips through working with pharmaceutical industries to help further develop the technology. In April 2025, FDA announced that the administration would be phasing out animal testing in replacement of human based models, such as organ chips. To implement this change, FDA will be updating policy and regulations to allow for new methods during drug testing. In doing so, FDA expects that this will accelerate drug testing and reveal human-specific side effects that may not be revealed during animal studies. The Human Liver-Chip was recently accepted into FDA’s Innovative Science and Technology for Advancing New Drugs pilot program, which allows for the use of drug development tools that do not meet regulatory standards but provide supportive data. This program is intended to aid in the acceptance of new drug development tools.
NASA has also expressed interest in the technology and plans to send organ chips to the Moon to study effects of gravity and space radiation. Microgravity from space travel can make the human body age at an accelerated rate. Researchers developed a program called Tissue Chips in Space 2.0 that sends organ chips to the International Space Station with the goal of studying the effects of microgravity to understand how diseases develop, test treatments, and improve astronaut health during space travel.