AI & Data Significance 7/10

Patient-Derived Xenograft Models for Functional Precision Oncology in the AI Era

This Nature Reviews Cancer paper examines how patient-derived xenograft (PDX) models enable functional precision oncology by moving beyond static molecular profiling to dynamic in vivo and ex vivo drug sensitivity testing. The authors explore the integration of PDX-derived functional data with AI-powered treatment prediction algorithms, proposing that this combination could deliver faster, more accurate, and cost-effective personalised treatment selection for cancer patients.

The original study

PDX models for functional precision oncology and discovery science.

Authors
Blanchard Z, Brown EA, Ghazaryan A, Welm AL
Journal
Nature reviews. Cancer
Type
Journal Article, Review
PMID
39681638
Read the original study →

Original abstract

Precision oncology relies on detailed molecular analysis of how diverse tumours respond to various therapies, with the aim to optimize treatment outcomes for individual patients. Patient-derived xenograft (PDX) models have been key to preclinical validation of precision oncology approaches, enabling the analysis of each tumour's unique genomic landscape and testing therapies that are predicted to be effective based on specific mutations, gene expression patterns or signalling abnormalities. To extend these standard precision oncology approaches, the field has strived to complement the otherwise static and often descriptive measurements with functional assays, termed functional precision oncology (FPO). By utilizing diverse PDX and PDX-derived models, FPO has gained traction as an effective preclinical and clinical tool to more precisely recapitulate patient biology using in vivo and ex vivo functional assays. Here, we explore advances and limitations of PDX and PDX-derived models for precision oncology and FPO. We also examine the future of PDX models for precision oncology in the age of artificial intelligence. Integrating these two disciplines could be the key to fast, accurate and cost-effective treatment prediction, revolutionizing oncology and providing patients with cancer with the most effective, personalized treatments.