Abstract
Objective and Impact Statement. We propose a rapid and accurate blood cell identification method exploiting deep learning and label-free refractive index (RI) tomography. Our computational approach that fully utilizes tomographic information of bone marrow (BM) white blood cell (WBC) enables us to not only classify the blood cells with deep learning but also quantitatively study their morphological and biochemical properties for hematology research. Introduction. Conventional methods for examining blood cells, such as blood smear analysis by medical professionals and fluorescence-activated cell sorting, require significant time, costs, and domain knowledge that could affect test results. While label-free imaging techniques that use a specimen's intrinsic contrast (e.g., multiphoton and Raman microscopy) have been used to characterize blood cells, their imaging procedures and instrumentations are relatively time-consuming and complex. Methods. The RI tomograms of the BM WBCs are acquired via Mach-Zehnder interferometer-based tomographic microscope and classified by a 3D convolutional neural network. We test our deep learning classifier for the four types of bone marrow WBC collected from healthy donors (): monocyte, myelocyte, B lymphocyte, and T lymphocyte. The quantitative parameters of WBC are directly obtained from the tomograms. Results. Our results show >99% accuracy for the binary classification of myeloids and lymphoids and >96% accuracy for the four-type classification of B and T lymphocytes, monocyte, and myelocytes. The feature learning capability of our approach is visualized via an unsupervised dimension reduction technique. Conclusion. We envision that the proposed cell classification framework can be easily integrated into existing blood cell investigation workflows, providing cost-effective and rapid diagnosis for hematologic malignancy.
Highlights
Accurate blood cell identification and characterization play an integral role in the screening and diagnosis of various diseases, including sepsis [1,2,3], immune system disorders [4, 5], and blood cancer [6]
These parameters can be directly obtained from the 3D refractive index (RI) tomograms
While the machine learning algorithms do not exceed 90% accuracy, our method achieved more than 96% test accuracy, as confirmed in the previous section
Summary
Accurate blood cell identification and characterization play an integral role in the screening and diagnosis of various diseases, including sepsis [1,2,3], immune system disorders [4, 5], and blood cancer [6]. Single cell profiling with morphological/biochemical features followed by the careful observation of blood cell alternations and cell count as per specific diseases This requires time, labor, and associated costs and is vulnerable to the variability of staining quality that depends on the staining of trained personnel. To address this issue, several label-free techniques for identifying blood cells have recently been explored, including multiphoton excitation microscopy [8, 9], Raman microscopy [10,11,12], and hyperspectral imaging [13, 14]. By measuring the optical path length delay induced by a specimen and by reconstructing a refractive index using the analytic relation between the scattered light and sample, QPI can identify and characterize the morphological and biochemical properties of various blood cells
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