KRAS and BRAF Mutation Analysis in Routine Molecular Diagnostics Comparison of Three Testing Methods on Formalin-Fixed, Paraffin-Embedded Tumor-Derived DNA

Accurate mutation detection assays are strongly needed for use in routine molecular pathology analyses to aid in the selection of patients with cancer for targeted therapy. The high-resolution melting (HRM) assay is an ideal prescreening tool, and SNaPshot analysis offers a straightforward genotyping system. Our present study was determined to compare these mutation testing methods on formalin-fixed, paraffin-embedded (FFPE) tumor derived DNA. We compared the performance of HRM, followed by cycle sequencing (HRM-sequencing); multiplex PCR assay, followed by SNaPshot analysis (multiplex mutation assay); and a successor assay using HRM, followed by SNaPshot (HRM-SNaPshot) for mutation analysis of both KRAS (codon 12/13/61) and BRAF (codon 600/601). In a series of 195 FFPE-derived DNA specimens, a high genotypic concordance between HRM-sequencing and multiplex mutation assay was found (kappa, 0.98; 95% CI, 0.94 to 1), underlining the potential of a combined HRM-SNaPshot approach. In reconstruction experiments, the analytical sensitivity of HRM-SNaPshot was twofold to fourfold higher than HRM-sequencing and multiplex mutation assay, respectively. In addition, HRM-SNaPshot had a good performance rate (99%) on FFPE tumor derived DNA, and mutation detection was highly concordant with the predecessor assays (K for both, 0.98). The occurrence of BRAF and KRAS mutations is mutually exclusive. HRM-SNaPshot is an attractive method for mutation analysis in pathology, given its good performance rate on FFPE-derived DNA, high analytical sensitivity, and prescreening approach. (J Mol Diagn 2012, 14:247-255; DOI: 10.1016/j.jmoldx.2012.01.011

PET‐CT Imaging of Polymeric Nanoparticle Tumor Accumulation in Patients

Several FDA/EMA-approved nanomedicines have demonstrated improved pharmacokinetics and toxicity profiles compared to their conventional chemotherapeutic counterparts. The next step to increase therapeutic efficacy depends on tumor accumulation, which can be highly heterogeneous. A clinical tool for patient stratification is urgently awaited. Therefore, a docetaxel-entrapping polymeric nanoparticle ( 89Zr-CPC634) is radiolabeled, and positron emission tomography/computed tomography (PET/CT) imaging is performed in seven patients with solid tumors with two different doses of CPC634: an on-treatment (containing 60 mg m −2 docetaxel) and a diagnostic (1–2 mg docetaxel) dose (NCT03712423). Pharmacokinetic half-life for 89Zr-CPC634 is mean 97.0 ± 14.4 h on-treatment, and 62.4 ± 12.9 h for the diagnostic dose (p = 0.003). At these doses accumulation is observed in 46% and 41% of tumor lesions with a median accumulation in positive lesions 96 h post-injection of 4.94 and 4.45%IA kg −1 (p = 0.91), respectively. In conclusion, PET/CT imaging with a diagnostic dose of 89Zr-CPC634 accurately reflects on-treatment tumor accumulation and thus opens the possibility for patient stratification in cancer nanomedicine with polymeric nanoparticles

PET-CT Imaging of Polymeric Nanoparticle Tumor Accumulation in Patients

Several FDA/EMA-approved nanomedicines have demonstrated improved pharmacokinetics and toxicity profiles compared to their conventional chemotherapeutic counterparts. The next step to increase therapeutic efficacy depends on tumor accumulation, which can be highly heterogeneous. A clinical tool for patient stratification is urgently awaited. Therefore, a docetaxel-entrapping polymeric nanoparticle (89Zr-CPC634) is radiolabeled, and positron emission tomography/computed tomography (PET/CT) imaging is performed in seven patients with solid tumors with two different doses of CPC634: an on-treatment (containing 60 mg m−2 docetaxel) and a diagnostic (1–2 mg docetaxel) dose (NCT03712423). Pharmacokinetic half-life for 89Zr-CPC634 is mean 97.0 ± 14.4 h on-treatment, and 62.4 ± 12.9 h for the diagnostic dose (p = 0.003). At these doses accumulation is observed in 46% and 41% of tumor lesions with a median accumulation in positive lesions 96 h post-injection of 4.94 and 4.45%IA kg−1 (p = 0.91), respectively. In conclusion, PET/CT imaging with a diagnostic dose of 89Zr-CPC634 accurately reflects on-treatment tumor accumulation and thus opens the possibility for patient stratification in cancer nanomedicine with polymeric nanoparticles