Noninvasive Measurement Enables Use of Interstitial Fluid Pressure as Potential Biomarker for Tumor Aggressiveness
- Higher IFP linked with treatment resistance and metastasis.
- Identification of IFP could dictate appropriate use of aggressive therapies.
- Further assessment of noninvasive measurement needed.
PHILADELPHIA — Researchers validated a method of noninvasive imaging that provides valuable information about interstitial fluid pressure of solid tumors and may aid in the identification of aggressive tumors, according to the results of a study published in Cancer Research, a journal of the American Association for Cancer Research.
Many malignant solid tumors generally develop a higher interstitial fluid pressure (IFP) than normal tissue. High IFP in tumors may cause a reduced uptake of chemotherapeutic agents and resistance to radiation therapy. In addition, a high IFP has been found to promote metastatic spread.
“Currently, an imaging method for noninvasive assessment of the IFP of tumors is needed to evaluate the potential of IFP as a biomarker for cancer aggressiveness and, hence, to identify patients with cancer who may benefit from particularly aggressive treatment because of highly elevated tumor IFP,” said Einar K. Rofstad, Ph.D., of the department of radiation biology at the Institute for Cancer Research, Norwegian Radium Hospital, Oslo, Norway.
Rofstad and colleagues tested the use of dynamic contrast-enhanced magnetic resonance imaging (MRI) to evaluate the velocity of fluid flow from tumors in human cell lines of cervical carcinoma and melanoma implanted in mice. Researchers hypothesized that the velocity of fluid flow from tumor tissue into adjacent tissue was determined by the IFP drop at the tumor surface.
Results indicated that the velocity of the fluid flow at the tumor surface strongly correlated with the magnitude of the tumor IFP and that dynamic contrast-enhanced MRI with gadolinium diethylene-triamine penta-acetic acid (Gd-DTPA) as a contrast agent can be used to noninvasively measure the fluid-flow velocity. In addition, primary tumors of mice with metastases had a significantly higher IFP and fluid-flow velocity at the tumor surface compared with the primary tumors of metastasis-free mice, confirming that the development of lymph node metastases strongly correlated to the IFP of the primary tumor and the velocity of fluid flow as measured by Gd-DTPA-based dynamic contrast-enhanced MRI.
“Our findings establish that Gd-DTPA-based dynamic contrast-enhanced MRI can noninvasively visualize tumor IFP,” Rofstad said. “This reveals the potential for the fluid-flow velocity at the tumor surface determined by this imaging method to serve as a novel general biomarker of tumor aggressiveness.”
Rofstad said that comprehensive prospective clinical investigations in several types of cancer are needed to assess the value of fluid-flow velocity at the tumor surface level assessed by Gd-DTPA-based dynamic contrast-enhanced MRI as a general biomarker for interstitial hypertension-induced cancer aggressiveness.