Understanding the possibility of image-guided thermal ablation for pulmonary malignancies

Proton Resonance Frequency Shift Thermometry: A Review of Modern Clinical Practices

Magnetic resonance imaging (MRI) has become a popular modality in guiding minimally invasive thermal therapies, due to its advanced, nonionizing, imaging capabilities and its ability to record changes in temperature. A variety of MR thermometry techniques have been developed over the years, and proton resonance frequency (PRF) shift thermometry is the current clinical gold standard to treat a variety of cancers. It is used extensively to guide hyperthermic thermal ablation techniques such as high-intensity focused ultrasound (HIFU) and laser-induced thermal therapy (LITT). Essential attributes of PRF shift thermometry include excellent linearity with temperature, good sensitivity, and independence from tissue type. This noninvasive temperature mapping method gives accurate quantitative measures of the temperature evolution inside biological tissues. In this review, the current status and new developments in the fields of MR-guided HIFU and LITT are presented with an emphasis on breast, prostate, bone, uterine, and brain treatments. LEVEL OF EVIDENCE: 5 TECHNICAL EFFICACY STAGE: 3.

Porphyrin-High-Density Lipoprotein: A Novel Photosensitizing Nanoparticle for Lung Cancer Therapy

BACKGROUND

We have developed ultrasmall porphyrin-high-density lipoprotein (HDL) nanoparticles (<20 nm), called "porphyrinHDL," that have a high density of porphyrin molecules and dissociate rapidly upon tumor cell accumulation to become fluorescent and photoactive. This is introduced as a novel activatable photosensitizer for image-guided photodynamic therapy (PDT). Here, we report the studies of these nanoparticles targeted to scavenger receptor class B type I (SR-BI) expressed on lung cancer cells as a first step toward development of a minimally invasive treatment for peripheral lung cancer and metastatic lymph nodes of advanced lung cancer.

METHODS

The in vitro uptake of porphyrinHDL and the corresponding PDT efficacy were evaluated in both SR-BI-positive and SR-BI-negative lung cancer cell lines. A clinically relevant orthotopic lung cancer model in mice was used to examine fluorescence activation and quantification of uptake in tumor. In addition, we investigated the effect of porphyrinHDL-mediated PDT.

RESULTS

PorphyrinHDL promoted proper intracellular uptake in the H460 human lung cancer cell line. When irradiated with a 671-nm PDT laser, porphyrinHDL produced significant therapeutic effectiveness in vitro. After systemic administration in mice with orthotopic lung cancer xenografts, porphyrinHDL demonstrated selective accumulation and photoactivation in tumor with significantly enhanced disease-to-normal tissue contrast. Moreover, porphyrinHDL-PDT significantly induced cell apoptosis in lung tumors (73.2%) without toxicity in normal tissues or damage to adjacent critical structures.

CONCLUSIONS

SR-BI-targeted porphyrinHDL-mediated PDT of lung cancer is selective and effective in vitro and in vivo. These initial proof-of-principle studies suggest the potential of a "smart" PDT approach for highly selective tumor ablation.