Abstract
The lensless on-chip microscope is an emerging technology in the recent decade that can realize the imaging and analysis of biological samples with a wide field-of-view without huge optical devices and any lenses. Because of its small size, low cost, and being easy to hold and operate, it can be used as an alternative tool for large microscopes in resource-poor or remote areas, which is of great significance for the diagnosis, treatment, and prevention of diseases. To improve the low-resolution characteristics of the existing lensless shadow imaging systems and to meet the high-resolution needs of point-of-care testing, here, we propose a high-precision on-chip microscope based on in-line holographic technology. We demonstrated the ability of the iterative phase recovery algorithm to recover sample information and evaluated it with image quality evaluation algorithms with or without reference. The results showed that the resolution of the holographic image after iterative phase recovery is 1.41 times that of traditional shadow imaging. Moreover, we used machine learning tools to identify and count the mixed samples of mouse ascites tumor cells and micro-particles that were iterative phase recovered. The results showed that the on-chip cell counter had high-precision counting characteristics as compared with manual counting of the microscope reference image. Therefore, the proposed high-precision lensless microscope on a chip based on in-line holographic imaging provides one promising solution for future point-of-care testing (POCT).
Highlights
IntroductionOptical microscopes play a significant role in scientific study and clinical testing in modern medicine and life sciences, as they can expand and identify morphological features of samples (including cells, bacteria, marine microorganisms, etc.) that cannot be enlarged and seen by the naked eyes
Optical microscopes play a significant role in scientific study and clinical testing in modern medicine and life sciences, as they can expand and identify morphological features of samples that cannot be enlarged and seen by the naked eyes
We demonstrated a lensless on-chip holographic imaging platform this paper, we demonstrated a lensless on-chip holographic imaging platform usingInin-line holography technology and used an iterative phase recovery algorithm to using in-line holography technology and used an iterative phase recovery algorithm to achieve the phase recovery of the holographic image
Summary
Optical microscopes play a significant role in scientific study and clinical testing in modern medicine and life sciences, as they can expand and identify morphological features of samples (including cells, bacteria, marine microorganisms, etc.) that cannot be enlarged and seen by the naked eyes. Due to large size, high cost, and complicated operation, these microscope detection platforms can only be used in advanced laboratories and medical institutions. Their scope and conditions of application are limited, especially in resource-limited areas where infectious diseases such as tuberculosis, malaria, sickle cell virus infection, and other diseases are common. The use of portable optical microscopes in resource-limited areas to improve detection efficiency is vital for preventing the spread of infectious diseases [12–14]. To meet such needs, in recent years, the combination of Complementary Metal Oxide
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