Researchers at the University of Toronto’s Leslie Dan Faculty of Pharmacy, working with collaborators around the world, have demonstrated the effectiveness of a suite of low-cost, portable biotechnology tools designed to improve access to laboratory research and diagnostics in resource-limited settings.

Published in Science Advances, the study highlights how decentralized biomanufacturing tools and freeze-dried reagents can help researchers produce high-value biological materials locally—reducing reliance on fragile international supply chains and expanding access to life sciences innovation globally.

The research was led by Keith Pardee, associate professor at the Leslie Dan Faculty of Pharmacy, alongside collaborators including Camila González in Bogotá, Colombia, Fernán Federici in Santiago, Chile, and Lindomar Pena in Recife, Brazil.

Prolonged manufacturing times for autologous CAR T cell therapies can be incompatible with rapidly progressive disease (PD), resulting in increased need for bridging therapy to achieve disease stabilization. Bridging therapy was required for most patients receiving cilta-cel and ide-cel in clinical trials (75 and 87%, respectively) (7, 9, 11, 12). Although use of bridging therapy may not affect ORR, CRR, or PFS, it is associated with worse overall survival (15). Similarly, as wait times for CAR T cell product increase, so does risk of mortality as effectiveness of the therapy decreases (16, 17), highlighting the need for improved CAR T cell products with faster and more reliable manufacturing.

Another issue associated with traditionally manufactured CAR T cell products is T cell exhaustion due to extended periods of in vitro stimulation and expansion during manufacturing (18). Higher levels of exhausted T cells were also observed in the leukapheresis material and final products from patients who later experienced PD (18). T cell exhaustion can result in poor persistence of CAR T cells in the body, thereby impeding function as the proliferation and survival of transferred T cells strongly correlate with their antitumor activity (19–22). Specific T cell populations have varying abilities to expand and persist in vivo. Memory (CD8⁺CD45RO⁻CD27⁺) and naive T cell (T_N cell) subsets are associated with improved clinical response, given their ability to proliferate and persist after infusion, whereas effector T cell subsets comparatively exhibit lower self-renewal and survival capabilities (19, 23, 24). Although these patient-specific parameters are initially established in leukapheresis material, preservation of such cell populations in the final product via manufacturing techniques may improve the antitumor activity of a patient’s CAR T cell therapy (18, 19, 23, 24).

Durcabtagene autoleucel (PHE885) is an autologous, BCMA-targeting CAR T cell therapy carrying a CAR construct with a fully human anti-BCMA single-chain fragment variable (scFv) fused to 4-1BB/CD3ζ signaling domains manufactured on a next-generation platform. Prior work has shown that this platform can successfully manufacture product in fewer than 2 days by eliminating the need for ex vivo expansion, thereby preserving overall T cell stemness (the ability of T cells to self-renew and mature), which results in a final product with greater proliferative potential and fewer exhausted T cells (18). Here, we present the findings of part A of the phase 1 study (NCT04318327) of durcabtagene autoleucel in r/r MM, along with correlative analyses of the product before and after infusion.

Renal oncocytic neoplasms present diagnostic challenges, both at imaging and pathologic evaluation. The World Health Organization classification of renal neoplasms defines a spectrum of oncocytic neoplasms, including emerging entities that help define previously uncharacterized or mischaracterized tumors. Low-grade oncocytic tumors and eosinophilic vacuolated tumors are distinguishable from other oncocytic neoplasms at pathologic evaluation and typically demonstrate indolent behavior. Nomenclature regarding hybrid neoplasms has been clarified in reference to hereditary cases associated with Birt-Hogg-Dubé syndrome. Preoperative diagnostic difficulties at imaging contribute to high rates of resected benign renal tumors, the majority being renal oncocytomas. The imaging appearances of oncocytic neoplasms are similar, and the inability to confidently diagnose them at imaging has led to increased resection rates. Preoperative renal mass biopsy may be preventative, but its utilization remains low, diagnoses can be equivocal, and establishing tumor aggressiveness may not always be reliable. Malignant renal oncocytic tumors, including chromophobe renal cell carcinoma, are generally considered the less aggressive subtypes of renal cell carcinoma. However, distinguishing them from the more aggressive clear cell subtype remains challenging, despite imaging frameworks designed to aid categorization. Active surveillance is a safe management option among biopsy-confirmed renal oncocytic neoplasms, but it remains uncertain which patients are suitable for this approach. Diagnostic imaging may assist in risk-stratifying oncocytic neoplasms, with mass enhancement, heterogeneity, and calcification potentially differentiating benign from malignant oncocytic neoplasms. Mass attenuation and heterogeneity may differentiate low-grade and high-grade cancers. Molecular imaging and other emerging techniques, such as MR fingerprinting, may play a role in the future.

^©RSNA, 2026

Supplemental material is available for this article.