1. Introduction
Growth and maintenance of cell and tissue cultures are predominantly determined by end-point investigation. However, determining proliferation and differentiation kinetics would enable monitoring of processes, which contribute to the outcome of end-point investigations. Applying live-cell imaging to monitor cell dynamics requires highly equipped microscopes, which are extremely expensive [
1]. Nevertheless, real-time in situ analysis of cell cultures is highly demanded by both research academia and industry in order to gain more insights into cell growth, including the cell dynamic behavior and morphology [
2]. Therefore, miniaturized microscopes, which enable lensless real-time imaging of cells inside a conventional CO2 cell culture incubator, are a promising inexpensive alternative.
In this work, a compact and inexpensive imaging device based on digital inline-holography was built and applied to living cell cultures both outside and inside a cell incubator environment. By means of computational image analysis, key parameters (e.g., cell count, size and movement) could be extracted from the imaging data. The setup was also tested and optimized for long-term measurement scenarios and continuous online cell observation.
2. Materials and Methods
2.1. Microscopy Setup
For observation of cell cultures, a digital inline-holographic microscope [
3] was built by utilizing a multi-color LED light source, a pinhole, and a CMOS sensor (
Figure 1). The multi-color light source, having illumination peaks at 466 nm, 517 nm, and 629 nm, respectively, was spatially filtered by a 90 μm pinhole and positioned at a distance of 60 mm over the image sensor. The biological sample inside a petri dish was placed directly on top of the image sensor, which determines the effective sample-to-sensor distance by the thickness of the bottom of the petri dish and its refractive index. For the image sensor, an ON Semiconductor MT9P031 with a resolution of 2592 × 1944 pixels and a pixel pitch of 2.2 μm was interfaced with a controller board and connected to a PC via USB 3.0. The controlling of the light source was performed by a microcontroller, which was also connected to the measurement PC. An appropriate housing for fixing the components and allowing both inside cell incubator and stand-alone operations has been fabricated out of non-transparently dyed poly(methyl methacrylate) (PMMA) by 3D printing technique.
The image acquisition was performed by a custom written software, which is controlling the switching of the desired colors of the light source, and is saving the image automatically after brightness control of the camera has been stabilized. The data was saved locally and streamed to a cloud storage for a remote observation.
2.2. Image Reconstruction and Examination
The obtained raw image data containing a diffraction image of the illuminated sample was reconstructed by an in-house written software using the angular spectrum approach [
4] allowing the extraction of both amplitude and phase information images from the microscopic data. Afterwards, cell counting based on blob detection or artificial neural network approach respectively was performed.
2.3. Samples
For testing and calibration of the developed microscope, polystyrene particles with various diameters (i.e., 1.3 μm, 5 μm, and 10 μm) as well as a USAF1951 resolution test chart were used. Meanwhile, in terms of the online measurements, immortalized mouse astrocyte cells (IMA, [
5]) in agarose nutrition medium and a MIN6 cell line were investigated.
3. Results
The preliminary examinations of the microscopic setup with the resolution and image quality test samples reveal a resolution down to 2.46 μm and a field-of-view of 24.4 mm². The combination of an inline-holographic microscope with living cell cultures for cell counting could be successfully performed revealing both amplitude (
Figure 2a) and phase images (
Figure 2b) of the culture. The images could be used for cell identification (
Figure 2c) by appropriate algorithms. In case of the IMA cells, the phase image shows a better contrast than the amplitude image. Cells that appear to be blurred in the amplitude image show up clearly in the phase image. Due to the automated timed acquisition of the measurements, time series of the cell cultures could be made, revealing cell movements (
Figure 3).
In order to validate the long-term operation, the microscope was placed inside a cell incubator (100% relative humidity by 37 °C and 5% CO2) for 3 days and adjusted to take a measurement automatically every 10 min with all 3 wavelengths of the light source. The data was both stored locally and streamed to a cloud storage device. Regardless of the required integration of a cooling device into the system due to the heated image sensor causing damage on the observed MIN6 cells, the developed microscope has been able to be operated without software or hardware malfunction over the whole time.
4. Discussion
The wide field-of-view, in combination with the sufficiently high resolution, can be used for the visualization and observation of cell culture growth. The difference in the amplitude and phase images allows an enhancement of the usable information content, while it also becomes apparent, that the used method has to be chosen carefully in order to avoid misleading results. The utilization of a timed acquisition software with cloud storage integration opens a path to study both cell dynamics and long-term cell observation, while the experimental setup has proven its capability to carry out such operations.
5. Conclusions
It has been demonstrated that the utilization of inline-holographic microscopy for cell culture investigation proves to be a promising way of revealing cell growth and dynamics during incubation. A system, capable of performing the task of long-term observation in combination with the acquisition of quantitative information like cell size, cell count and mobility has been presented. Nevertheless, further optimization of the system in both hardware and software is still required to completely unlock the full potential of this approach. An advantageous use of this compact microscope in combination with transparent microfluidic cell cultivation is foreseen. This can give a new insight into cell cultures, which finally can lead to new potential cure methods in medical research and therapy.
Author Contributions
Conceptualization, G.S., S.M., I.S., A.B.D. and H.S.W.; Methodology, G.S.; Software, A.B.D., I.S. and G.S.; Validation, J.H., P.H. and T.S.; Formal Analysis, A.B.D.; Investigation, I.S.; Resources, T.S., K.M., P.H., A.D., I.R., and K.H.; Data Curation, G.S.; Writing-Original Draft Preparation, G.S.; Writing-Review & Editing, J.H., J.D.P., H.S.W.; Visualization, G.S.; Supervision, H.S.W. and A.W.; Project Administration, H.S.W. and A.W.; Funding Acquisition, A.W.
Funding
This work is performed within projects of LENA-OptoSense and QUANOMET funded by the Lower Saxony Ministry for Science and Culture, Germany, as well as European project of ChipScope funded by the European Union’s Horizon 2020 research and innovation program under grant agreement No. 737089.
Acknowledgments
The authors thank K.-H. Lachmund for the technical support. S.M. thanks the Georg-Christoph-Lichtenberg PhD scholarship (Tailored Light). A.B.D. thanks Kemenristekdikti-LPDP for the Ph.D. scholarship. I.S. acknowledges RISTEKDIKTI for the Ph.D. scholarship of RISET-Pro. J.D.P. acknowledges the support of the European Unionʹs Seventh Framework Program (FP/2007-2013)/ERC Grant Agreement n. 336917, the Serra Húnter Program and the DFG Project GrK NanoMet.
Conflicts of Interest
The authors declare no conflict of interest.
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