Your search keyword '"Espinoza AF"' showing total 3 results

1. Quantitative ctDNA Detection in Hepatoblastoma: Implications for Precision Medicine.

Author

Kahana-Edwin S, Torpy J, Cain LE, Mullins A, McCowage G, Woodfield SE, Vasudevan SA, Shea DPT, Minoche AE, Espinoza AF, Kummerfeld S, Goldstein LD, and Karpelowsky J

Abstract

Hepatoblastoma is characterized by driver mutations in CTNNB1 , making it an attractive biomarker for a liquid biopsy approach utilizing circulating tumor DNA (ctDNA). This prospective observational study sought to ascertain the feasibility of ctDNA detection in patients with hepatoblastoma and explore its associations with established clinical indicators and biomarkers, including serum Alpha-fetoprotein (AFP). We obtained 38 plasma samples and 17 tumor samples from 20 patients with hepatoblastoma. These samples were collected at various stages: 10 at initial diagnosis, 17 during neoadjuvant chemotherapy, 6 post-operatively, and 5 at disease recurrence. Utilizing a bespoke sequencing assay we developed called QUENCH, we identified single nucleotide variants and deletions in CTNNB1 ctDNA. Our study demonstrated the capability to quantitate ctDNA down to a variant allele frequency of 0.3%, achieving a sensitivity of 90% for patients at initial diagnosis, and a specificity of 100% at the patient level. Notably, ctDNA positivity correlated with tumor burden, and ctDNA levels exhibited associations with macroscopic residual disease and treatment response. Our findings provide evidence for the utility of quantitative ctDNA detection in hepatoblastoma management. Given the distinct detection targets, ctDNA and AFP-based stratification and monitoring approaches could synergize to enhance clinical decision-making. Further research is needed to elucidate the interplay between ctDNA and AFP and determine the optimal clinical applications for both methods in risk stratification and residual disease detection.

Published

2023

2. Pediatric Hepatocellular Adenomas: What Is Known and What Is New?

Author

Espinoza AF, Vasudevan SA, Masand PM, Lòpez-Terrada DH, and Patel KR

Abstract

Current understanding and classification of pediatric hepatocellular adenomas (HCA) are largely based on adult data. HCAs are rare in children and, unlike in adults, are often seen in the context of syndromes or abnormal background liver. Attempts to apply the adult classification to pediatric tumors have led to several "unclassifiable" lesions. Although typically considered benign, few can show atypical features and those with beta-catenin mutations have a risk for malignant transformation. Small lesions can be monitored while larger (>5.0 cm) lesions are excised due to symptoms or risk of bleeding/rupture, etc. Management depends on gender, age, underlying liver disease, multifocality, size of lesion, histologic subtype and presence of mutation, if any. In this review, we summarize the data on pediatric HCAs and highlight our experience with their diagnosis and management.

Published

2023

3. Trial Sponsorship and Time to Reporting for Phase 3 Randomized Cancer Clinical Trials.

Author

Lin TA, Fuller CD, Verma V, Mainwaring W, Espinoza AF, Miller AB, Jethanandani A, Pasalic D, Das P, Minsky BD, Thomas CR Jr, Fogelman DR, Subbiah V, Subbiah IM, and Ludmir EB

Abstract

The pace of clinical trial data generation and publication is an area of interest within clinical oncology; however, little is known about the dynamics and covariates of time to reporting (TTR) of trial results. To assess these, ClinicalTrials.gov was queried for phase three clinical trials for patients with metastatic solid tumors, and the factors associated with TTR from enrollment completion to publication were analyzed. Based on the 319 included trials, cooperative-group-sponsored trials were reported at a slower rate than non-cooperative-group trials (median 37.5 vs. 31.0 months; p < 0.001), while industry-funded studies were reported at a faster rate than non-industry-supported trials (31.0 vs. 40.0 months; p = 0.005). Furthermore, successful trials (those meeting their primary endpoint) were reported at a faster rate than unsuccessful studies (27.5 vs. 36.0 months; p < 0.001). Multivariable analysis confirmed that industry funding was independently associated with a shorter TTR ( p = 0.006), while cooperative group sponsorship was not associated with a statistically significant difference in TTR ( p = 0.18). These data underscore an opportunity to improve cooperative group trial efficiency by reducing TTR.

Published

2020