Interrelation between Spectral Online Monitoring and Postoperative T1-Weighted MRI in Interstitial Photodynamic Therapy of Malignant Gliomas

• Published in: Cancers Vol. 14; no. 1; p. 120
• Main Authors: Aumiller, Maximilian, Heckl, Christian, Quach, Stefanie, Stepp, Herbert, Ertl-Wagner, Birgit, Sroka, Ronald, Thon, Niklas, Rühm, Adrian
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 27.12.2021; MDPI
• Subjects: Brain tumors; Fluorescence; Glioblastoma; Hemoglobin; Investigations; Lasers; Magnetic resonance imaging; malignant glioma; glioblastoma; photodynamic therapy; interstitial photodynamic therapy; 5-ALA; protoporphyrin IX; online monitoring; fluorescence; T1 hyperintensity; methemoglobin; Medical prognosis; Methemoglobin; Neuroimaging; Optics; Patients; Photodynamic therapy; Protoporphyrin; Protoporphyrin IX; Radiation; Statistical analysis; Tumor cells; Germany; glioblastoma; protoporphyrin IX; fluorescence; photodynamic therapy; methemoglobin; T1 hyperintensity; malignant glioma; 5-ALA; online monitoring; interstitial photodynamic therapy
• ISSN: 2072-6694; 2072-6694
• DOI: 10.3390/cancers14010120

In a former study, interstitial photodynamic therapy (iPDT) was performed on patients suffering from newly diagnosed glioblastoma (n = 11; 8/3 male/female; median age: 68, range: 40–76). The procedure includes the application of 5-ALA to selectively metabolize protoporphyrin IX (PpIX) in tumor cells and illumination utilizing interstitially positioned optical cylindrical diffuser fibers (CDF) (2–10 CDFs, 2–3 cm diffusor length, 200 mW/cm, 635 nm, 60 min irradiation). Intraoperative spectral online monitoring (SOM) was employed to monitor treatment light transmission and PpIX fluorescence during iPDT. MRI was used for treatment planning and outcome assessment. Case-dependent observations included intraoperative reduction of treatment light transmission and local intrinsic T1 hyperintensity in non-contrast-enhanced T1-weighted MRI acquired within one day after iPDT. Intrinsic T1 hyperintensity was observed and found to be associated with the treatment volume, which indicates the presence of methemoglobin, possibly induced by iPDT. Based on SOM data, the optical absorption coefficient and its change during iPDT were estimated for the target tissue volumes interjacent between evaluable CDF-pairs at the treatment wavelength of 635 nm. By spatial comparison and statistical analysis, it was found that observed increases of the absorption coefficient during iPDT were larger in or near regions of intrinsic T1 hyperintensity (p = 0.003). In cases where PpIX-fluorescence was undetectable before iPDT, the increase in optical absorption and intrinsic T1 hyperintensity tended to be less. The observations are consistent with in vitro experiments and indicate PDT-induced deoxygenation of hemoglobin and methemoglobin formation. Further investigations are needed to provide more data on the time course of the observed changes, thus paving the way for optimized iPDT irradiation protocols.