A live tumor fragment platform to assess immunotherapy response in core needle biopsies while addressing challenges of tumor heterogeneity

  1. T.S. Ramasubramanian
  2. Pichet Adstamongkonkul
  3. Christina M. Scribano
  4. Christin Johnson
  5. Sean Caenepeel
  6. Laura C.F. Hrycyniak
  7. Lindsey Vedder
  8. Nicholas Dana
  9. Christian Baltes
  10. Torey Browning
  11. Yuan-I Chen
  12. Thomas Dietz
  13. Evan Flietner
  14. Nicholas Kaplewski
  15. Anna Kellner
  16. Michael Korrer
  17. Chao Liu
  18. Nathan Marhefke
  19. Payton McDonnell
  20. Amreen Nasreen
  21. Victoria Pope
  22. Abhijeet Prasad
  23. Jordyn Richardson
  24. Sidney Schneider
  25. Mikaela Schultz
  26. Chetan Sood
  27. Aishwarya Sunil
  28. Erika von Euw
  29. Eric Wait
  30. Ellen Wargowski
  31. Pooja Advani
  32. Barbara Broome
  33. Antje Bruckbauer
  34. Andrew Godwin
  35. Nima Kokabi
  36. Robert Martin
  37. Mercedes Robaina
  38. Giuseppe Toia
  39. Joshua Routh
  40. Andreas Friedl
  41. Kevin Eliceiri
  42. Mike Szulczewski
  43. Scott Johnson
  44. Jon Oliner
  45. Jérôme Galon
  46. Christian Capitini
  47. Debabrata Mukhopadhyay
  48. Janis Taube
  49. David Braun
  50. Hinco J. Gierman
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Abstract

Background

Immune checkpoint inhibitors (ICIs) have revolutionized cancer treatment, providing durable and even curative responses. However, most patients do not respond and current biomarkers (eg, programmed death ligand (PD-L1), mismatch repair deficiency (dMMR)/high microsatellite instability (MSI) and tumor mutational burden) lack predictive accuracy. Ex vivo profiling of patient-derived tumor fragments shows promise as a predictive biomarker but relies on substantial surgical tissue to mitigate intra-specimen heterogeneity. Innovations are needed that address these challenges, particularly where limited tissue is available in core needle biopsies (CNBs).

Methods

Live tumor fragments (LTFs) were generated from 59 human tumor resections and 31 CNBs from patients enrolled in observational clinical trials (ClinicalTrials.gov identifiers: <ext-link xmlns:xlink="http://www.w3.org/1999/xlink" ext-link-type="clintrialgov" xlink:href="NCT05478538">NCT05478538</ext-link>, <ext-link xmlns:xlink="http://www.w3.org/1999/xlink" ext-link-type="clintrialgov" xlink:href="NCT05520099">NCT05520099</ext-link>, <ext-link xmlns:xlink="http://www.w3.org/1999/xlink" ext-link-type="clintrialgov" xlink:href="NCT06349642">NCT06349642</ext-link>) to assess cytokine induction following ICI treatment. LTFs were encapsulated in hydrogel and cultured ex vivo for up to 72 hours. A sequential treatment strategy that applies control and treatment within the same well was used with response to ICI or αCD3/αCD28 assessed using a multiplex secretome assay. Viability was assessed using established metabolic assays and dynamic optical coherence microscopy.

Results

LTFs maintained viability and retained T cells responsive to stimulation throughout ex vivo culture. Multiplex immunofluorescence and immunohistochemistry showed key components of the tumor microenvironment, including relative proportions of CD4+ and CD8+ immune cell populations, were preserved. Specimens positive for PD-L1 or dMMR/MSI-high were enriched for cytokine upregulation, including T-cell response cytokines IFNγ and CXCL10, after αPD-1 treatment. To demonstrate clinical applicability of the sequential treatment strategy, CNBs from patients with lung, gastrointestinal or kidney cancer were profiled and differential cytokine induction in response to ICI treatment was observed.

Conclusions

The novel ex vivo platform presented is capable of detecting T-cell response to ICI treatment by using a sequential treatment strategy. This approach addresses challenges associated with cross-well heterogeneity in tissue composition and requires half as much tissue as a cross-well comparison, mitigating tissue limitations typically associated with non-surgical biopsies. Importantly, the platform is compatible with established functional assays as well as non-destructive spatial imaging, enabling researchers to characterize response to ICI longitudinally. Ongoing trials will enable clinicians to assess platform performance in predicting response to immunotherapy.

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