CT Parametric Response Mapping Technology Can Distinguish Types of Lung Injury

By MedImaging International staff writers
Posted on 16 Oct 2012
A new approach designed for lung scanning could improve the diagnosis and treatment of a lung disease called chronic obstructive pulmonary disease (COPD), which is the United States’ third-highest cause of death.

In a new study published October 7, 2012, online in the journal Nature Medicine, the University of Michigan (U-M) Medical School (Ann Arbor, MI, USA) investigators reported on a technique called parametric response mapping (PRM). They used PRM to study computed tomography (CT) scans of the lungs of patients with COPD, who took part in a COPDGene study funded by the US National Heart, Lung and Blood Institute (Bethesda, MD, USA).

The researchers reported that the PRM technique for evaluating CT scans could better differentiate between early-stage damage to the small airways of the lungs, and more severe damage known as emphysema. They have also demonstrated that the overall severity of a patient’s disease, as measured with PRM, correlates closely with the patient’s performance on traditional lung tests based on breathing ability.

“Essentially, with the PRM technique, we’ve been able to tell subtypes of COPD apart, distinguishing functional small airway disease, or fSAD, from emphysema and normal lung function,” said Brian Ross, PhD, the a research professor of radiology, professor of biological chemistry and senior author of the article. “We believe this offers a new path to more precise diagnosis and treatment planning, and a useful tool for precisely assessing the impact of new medications and other treatments.”

“In the last decade, CT scan techniques for imaging COPD have improved steadily, but PRM is the missing link--giving us a robust way to see small airway disease and personalize treatment,” said Ella Kazerooni, MD, MS, FACS, a radiology professor who leads U-M’s lung imaging program and is a member of the COPDGene trial.

Originally developed to show the response of brain tumors to treatment, the PRM technique allows researchers to identify COPD specific changes in three-dimensional (3D) lung regions over time. A U-M spinoff company, Imbio (Minneapolis, MN, USA; http://imbio.com), has licensed U-M’s patents on the PRM technique, and is developing the technology for use in early prediction of treatment response of brain tumors and other cancers. Imbio has now begun developing PRM for COPD subtype diagnosis and tracking.

With the PRM technique, the researchers use computer techniques to overlay the CT scan taken during a full inhalation with an image captured during a full exhalation. The overlaid (registered) CT images share the same geometric space; therefore, the lung tissue in the inflated and deflated lungs aligns. Healthy lung tissue’s density will change more between the two images than the density of diseased lung, allowing researchers to create a 3D “map” of the patient’s lungs.

PRM assign colors to each small 3D area, called a voxel, according to the difference in signal changes within each of the areas between the two scans. Green means healthy, yellow means a reduced ability to push air out of the small sacs, and red means severely reduced ability.

“By distinguishing small airway abnormality from that involving the lung parenchyma, such as emphysema, PRM could help physicians personalize therapy for individual COPD patients--and select patients for clinical trials of new treatment options more precisely,” stated cosenior author Fernando Martinez, MD, MS, an internal medicine professor who is also participated in the COPDGene trial.

“PRM can also help to track COPD progression or response to treatment over time,” remarked lead author Dr. Craig Gabán, assistant professor of radiology. Although the current study typically looked at a “snapshot” of CT scans taken a one time, it also includes data on two U-M COPD patients who were imaged over more than two years. More longitudinal data are needed to determine that PRM works well for long-term monitoring and studies are ongoing.

Whereas a simple breathing test called spirometry is still considered the best way to diagnose the disease, spirometry has limitations in its ability to differentiate between diverse types of lung injury that COPD patients experience.

“The PRM technique is a step forward in being able to better sub-classify patients with COPD so that targeted therapies can be developed,” stated lead author MeiLan Han, MD, MS, a U-M pulmonologist and COPDGene investigator. “This is one of many important studies that is being made possible by the data being collected through NHLBI funded COPD initiatives.”

Related Links:

University of Michigan Medical School
Imbio



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