A machine-learning model that incorporates CD45 surface expression predicts hematopoietic progenitor cell recovery after freeze–thaw

Stem Cell
Machine Learning
Data Science
R
TidyModels
We developed a machine learning model for prediction of viable CD34+ HPC procurement after cryopreservation.
Author

Arwa Z. Al-Riyami, Elena Maryamchik, Richard S. Hanna, Amir Reza Pashmineh Azar, Xingwu Zheng, Shilpa Choudhari, Colleen Finn, Nicholas Giacobbe, Rene Machietto, Robert Rieser, Farzaneh Ghasemi Tahrir, Xiaoyong Zhang, Stephan Kadauke, Yongping Wang

Published

October 23, 2023

Doi

Abstract

Background aims

Sufficient doses of viable CD34+ (vCD34) hematopoietic progenitor cells (HPCs) are crucial for engraftment. Additional-day apheresis collections can compensate for potential loss during cryopreservation but incur high cost and additional risk. To aid predicting such losses for clinical decision support, we developed a machine-learning model using variables obtainable on the day of collection.

Methods

In total, 370 consecutive autologous HPCs, apheresis-collected since 2014 at the Children’s Hospital of Philadelphia, were retrospectively reviewed. Flow cytometry was used to assess vCD34% on fresh products and thawed quality control vials. The ratio of vCD34% thawed to fresh, which we call “post-thaw index,” was used as an outcome measure, with a “poor” post-thaw index defined as <70%. HPC CD45 normalized mean fluorescence intensity (MFI) was calculated by dividing CD45 MFI of HPCs to the CD45 MFI of lymphocytes in the same sample. We trained XGBoost, k-nearest neighbor and random forest models for the prediction and calibrated the best model to minimize falsely-reassuring predictions.

Results

In total, 63 of 370 (17%) products had a poor post-thaw index. The best model was XGBoost, with an area under the receiver operator curve of 0.83 evaluated on an independent test data set. The most important predictor for a poor post-thaw index was the HPC CD45 normalized MFI. Transplants after 2015, based on the lower of the two vCD34% values, showed faster engraftment than older transplants, which were based on fresh vCD34% only (average 10.6 vs 11.7 days, P = 0.0006).

Conclusions

Transplants taking into account post-thaw vCD34% improved engraftment time in our patients; however, it came at the cost of unnecessary multi-day collections. The results from applying our predictive algorithm retrospectively to our data suggest that more than one-third of additional-day collections could have been avoided. Our investigation also identified CD45 nMFI as a novel marker for assessing HPC health post-thaw.