Aarhus University12.21.15
For the first time, researchers have succeeded in producing 3D images showing oxygen and CO2 transport in the lungs. The new method provides hope for better treatment of COPD and lung cancer.
Every time we breathe, oxygen and CO2 is transferred between our blood and the air in the lungs. It is crucial for us to maintain life that this gas transport functions, and detailed knowledge about the movement of oxygen and CO2 is therefore also important. Not least in the case of patients with pulmonary lung diseases such as COPD, lung cancer, and asthma, and also for acutely ill patients who are on a respirator.
For these patients, the latest research in the area may turn out to be the first step on the road to more effective forms of treatment.
"We are the first to develop a new model for how you can see into the lungs. The model provides a kind of 3-D map of how and where the CO2 and oxygen transfers take place," said engineer and Ph.D. student Troels Johansen from the Department of Clinical Medicine at Aarhus University.
Working in collaboration with researchers from Harvard Medical School, Johansen has developed a mathematical model as part of his Ph.D. project that provides the basis for the 3-D images, which in turn are developed from PET scans.
The new method has just been published in an article in the scientific journal Respiratory Physiology & Neurobiology.
Images Give Better Treatment
The new model can be used for different groups of patients.
"For example, if we take cancer patients with a tumor in the lung, it will be easier to predict the consequences of removing part of the lung by surgery. It will also be easier for doctors to determine the COPD patients who will benefit from an operation and those who will not. We also believe that the new model will come to contribute with knowledge that can help patients in intensive care who are on a respirator," said Johansen. "The new model is not only able to make it easier for doctors to foresee the consequences of high-risk lung operations; it will also contribute new basic knowledge about the crucial oxygen and CO2 transfer in both healthy and diseased lungs."
Every time we breathe, oxygen and CO2 is transferred between our blood and the air in the lungs. It is crucial for us to maintain life that this gas transport functions, and detailed knowledge about the movement of oxygen and CO2 is therefore also important. Not least in the case of patients with pulmonary lung diseases such as COPD, lung cancer, and asthma, and also for acutely ill patients who are on a respirator.
For these patients, the latest research in the area may turn out to be the first step on the road to more effective forms of treatment.
"We are the first to develop a new model for how you can see into the lungs. The model provides a kind of 3-D map of how and where the CO2 and oxygen transfers take place," said engineer and Ph.D. student Troels Johansen from the Department of Clinical Medicine at Aarhus University.
Working in collaboration with researchers from Harvard Medical School, Johansen has developed a mathematical model as part of his Ph.D. project that provides the basis for the 3-D images, which in turn are developed from PET scans.
The new method has just been published in an article in the scientific journal Respiratory Physiology & Neurobiology.
Images Give Better Treatment
The new model can be used for different groups of patients.
"For example, if we take cancer patients with a tumor in the lung, it will be easier to predict the consequences of removing part of the lung by surgery. It will also be easier for doctors to determine the COPD patients who will benefit from an operation and those who will not. We also believe that the new model will come to contribute with knowledge that can help patients in intensive care who are on a respirator," said Johansen. "The new model is not only able to make it easier for doctors to foresee the consequences of high-risk lung operations; it will also contribute new basic knowledge about the crucial oxygen and CO2 transfer in both healthy and diseased lungs."