Simultaneous Detection of Multiple Tumor-targeted Gold Nanoparticles in HER2-Positive Breast Tumors Using Optoacoustic Imaging.

Purpose To develop optoacoustic, spectrally distinct, actively targeted gold nanoparticle-based near-infrared probes (trastuzumab [TRA], TRA-Aurelia-1, and TRA-Aurelia-2) that can be individually identifiable at multispectral optoacoustic tomography (MSOT) of human epidermal growth factor receptor 2 (HER2)-positive breast tumors. Materials and Methods Gold nanoparticle-based near-infrared probes (Aurelia-1 and 2) that are optoacoustically active and spectrally distinct for simultaneous MSOT imaging were synthesized and conjugated to TRA to produce TRA-Aurelia-1 and 2. Freshly resected human HER2-positive (n = 6) and HER2-negative (n = 6) triple-negative breast cancer tumors were treated with TRA-Aurelia-1 and TRA-Aurelia-2 for 2 hours and imaged with MSOT. HER2-expressing DY36T2Q cells and HER2-negative MDA-MB-231 cells were implanted orthotopically into mice (n = 5). MSOT imaging was performed 6 hours following the injection, and the Friedman test was used for analysis. Results TRA-Aurelia-1 (absorption peak, 780 nm) and TRA-Aurelia-2 (absorption peak, 720 nm) were spectrally distinct. HER2-positive human breast tumors exhibited a significant increase in optoacoustic signal following TRA-Aurelia-1 (28.8-fold) or 2 (29.5-fold) (P = .002) treatment relative to HER2-negative tumors. Treatment with TRA-Aurelia-1 and 2 increased optoacoustic signals in DY36T2Q tumors relative to those in MDA-MB-231 controls (14.8-fold, P < .001; 20.8-fold, P < .001, respectively). Conclusion The study demonstrates that TRA-Aurelia 1 and 2 nanoparticles operate as a spectrally distinct HER2 breast tumor-targeted in vivo optoacoustic agent. Keywords: Molecular Imaging, Nanoparticles, Photoacoustic Imaging, Breast Cancer Supplemental material is available for this article. © RSNA, 2023.

A phase I trial of oxaliplatin for intraperitoneal hyperthermic chemoperfusion for the treatment of peritoneal surface dissemination from colorectal and appendiceal cancers.

BACKGROUND: Cytoreductive surgery with intraperitoneal hyperthermic chemoperfusion (IPHC) has evolved into a promising approach for peritoneal surface malignancy. A large body of literature suggests that oxaliplatin has excellent cytotoxicity against colorectal cancer. Therefore, we undertook a phase I evaluation of IPHC with oxaliplatin for peritoneal dissemination from colorectal and appendiceal cancers to establish the dose-limiting toxicity (DLT) and the maximum tolerated dose (MTD). METHODS: Cohorts of three patients underwent cytoreductive surgery followed by a 2-h IPHC with escalating doses of oxaliplatin at a target outflow temperature of 40 degrees C. The initial peritoneal oxaliplatin dose was 200 mg/M(2) with increases planned in 50 mg/M(2 )increments. Plasma and perfusate samples were collected during the IPHC and evaluated using emission spectrometry techniques. Normal tissue and tumor samples were collected before and after the IPHC for analysis. DLT was defined as a grade 3 toxicity lasting 5 days. RESULTS: Fifteen patients were enrolled at two dose levels. Peritoneal fluid areas under the curve (AUCs) were above those of plasma. Additionally, intratumoral oxaliplatin was similar to that of surrounding normal tissue. Dose-limiting toxicities at 250 mg/M(2 )were observed in two of three patients enrolled in this study. CONCLUSION: We found that IPHC with 200 mg/M(2 )of oxaliplatin is well tolerated and is the MTD for a 2-h chemoperfusion. Higher doses are not feasible with this perfusion protocol given the significant toxicities associated with 250 mg/M(2 )oxaliplatin. Based on the data from this phase I study, we propose to conduct further studies with oxaliplatin delivered at 200 mg/M(2).