Harmonic Nanoparticles for Regenerative Research

Podsumowanie

Protocol details are provided for in vitro labeling human embryonic stem cells with second harmonic generating nanoparticles. Methodologies for hESC investigation by multi-photon microscopy and their differentiation into cardiac clusters are also presented.

Streszczenie

In this visualized experiment, protocol details are provided for in vitro labeling of human embryonic stem cells (hESC) with second harmonic generation nanoparticles (HNPs). The latter are a new family of probes recently introduced for labeling biological samples for multi-photon imaging. HNPs are capable of doubling the frequency of excitation light by the nonlinear optical process of second harmonic generation with no restriction on the excitation wavelength.

Multi-photon based methodologies for hESC differentiation into cardiac clusters (maintained as long term air-liquid cultures) are presented in detail. In particular, evidence on how to maximize the intense second harmonic (SH) emission of isolated HNPs during 3D monitoring of beating cardiac tissue in 3D is shown. The analysis of the resulting images to retrieve 3D displacement patterns is also detailed.

Wprowadzenie

Nonlinear microscopy systems, thanks to their inherent three dimensional sectioning capabilities, have increasingly triggered the demand for photo-stable fluorophores with two-photon absorption bands in the near-infrared. Only in the last couple of years, to complement the development of fluorescence-based labels (dyes, quantum dots, up-converting nanoparticles), a different imaging methodology has been exploiting the use of a novel family of inherently nonlinear nanoparticles as labels, i.e. harmonic nanoparticles (HNPs) which have been specifically developed for multi-photon microscopy. These labels, based on inorganic noncentrosymmetric crystals, exert optical contrast generating the SH of the excitation frequency: for example by converting a fraction of near infrared pulsed excitation light (λ = 800 nm) into visible blue light (λ/2 = 400 nm). Several authors in the recent past have tested different materials, including iron iodate Fe(IO₃)₃ ¹, potassium niobate (KNbO₃)², lithium niobate (LiNbO₃)³, barium titanate (BaTiO₃)^4,5, potassium titanyl phosphate (KTiOPO4, KTP)^6-8, and zinc oxide (ZnO)^5,9,10. Compared to fluorescent probes, HNPs possess a series of attractive properties, such as complete absence of bleaching and blinking, narrow emission bands, excitation-wavelength tunability (from ultraviolet to infrared), orientation retrieval capability, and coherent optical response. These unique properties have been recently explained in two comprehensive review papers^11,12. The possibility of working in the infrared spectral region, which increases imaging depth by minimizing scattering and absorption, also drastically limits sample photo degradation^13,14. Moreover, the infinitely photo-stable signal guaranteed by HNPs makes them ideal probes for long-term cell tracking, which is particularly appealing for regenerative medicine applications¹⁵.

In this visualized experiment, protocol details are provided for in vitro labeling of human embryonic stem cells (hESC) with unfunctionalized HNPs. The synthesis and preparation of colloidal suspensions is detailed in a previous publication and in references therein¹⁶ and is beyond the scope of this work. Methodologies for hESC investigation by multi-photon microscopy and their differentiation into cardiac clusters (maintained as long term air-liquid cultures) are presented. Human ESC can be let to differentiate within so called embryoid bodies (EBs) in two different ways, either by EB formation of colony fragments in suspension or, alternatively, forced aggregation of single cells into EBs using the Aggrewell plate, as illustrated in Figure 1A. Culturing beating clusters of cardiac cells on polytetrafluoroethylene (PTFE) porous filters facilitates their long-term maintenance for further studies (for example electrophysiological measurements of action potentials).

The excitation source of the scanning microscope should be able to deliver ultrashort pulses (with a pulse duration smaller than 300 fsec at the sample) in order to reach the peak power needed to perform second harmonic imaging of HNPs. For instance, the most common fsec-source used for imaging are tunable Ti:Sapphire lasers. Alternatively, other ultrafast lasers can be employed, for instance erbium ion¹⁷, chrome forsterite¹⁸ or Ti:sapphire pumped infrared optical parametric oscillators. The microscope can be equipped with an objective with preferably a rather high numerical aperture. Very importantly, prior to measurements, and each time the objective is replaced, it is mandatory to minimize the dispersion present in the set-up (lenses) by optimizing the settings of the laser pulse pre-compressor at the working wavelength of choice. This procedure, detailed in the protocol, ensures that the laser pulse is as close as possible to the transform limited duration (i.e. shortest as possible) at the focal plane and maximizes the sample nonlinear response.

The goal of the image analysis described at the end of the protocol is to identify and track in 3D HNPs movements associated with the rhythmic contractions of beating cardiac clusters. Tracking nanoparticles in the image plane is simply realized by identifying their positions in successive movie frames. To extract information on axial movement, a prior calibration of the nonlinear intensity response as a function of axial displacement is mandatory. Note that for long-term measurements, an active interferometric control of sample axial position is required to maintain the validity of the calibration curve in the presence of thermal and/or mechanical drifts.

The HNPs used here to trace beating cells within aggregates are based on potassium niobate oxide (KNbO₃), but other available nonlinear nanomaterials are reviewed in detail in the work of Staedler et al¹⁶.

The nonlinear optical efficiencies of most of the nanomaterials investigated so far are very comparable. The choice for KNbO₃ was essentially motivated by the good stability of the colloidal solution and its good biocompatibility, tested on several human cell lines even at fairly high concentration and long exposition times¹⁶.

Given the novelty of the nanomaterial employed for this work, the main characteristics of HNPs as compared to fluorescent/luminescent bio-markers are shown in a short original computer video animation realized by the authors.

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Protokół

1. Culture and Expansion of Human ESC

1. Prepare the cell propagation medium (called PM) containing Knockout DMEM supplemented with 20% Knockout Serum, 1% MEM Non-Essential Amino Acids, 1% L-glutamine 200 mM, 1% penicillin-streptomycin, and 3.5 µl β-mercaptoethanol.
2. Thaw human ESC (hESC) in 8 ml PM medium and centrifuge them 5 min at 115 x g to discard DMSO-supplemented freezing medium.
3. Add 1 ml of PM medium containing 10 mM Rock inhibitor to prevent apoptosis and improve cell survival upon thawing (24 hr incubation only).
4. Add basic fibroblast growth factor (bFGF) to the PM at the desired concentration (4-10 ng/ml) for maintenance of pluripotency.
5. Plate the hESC on irradiated human foreskin feeder cells (γHFF) (Figure 1A), previously plated at a concentration of 2 x 10⁴ cells/cm².
6. Change medium daily and, when necessary, remove portions of colonies starting to differentiate by aspiration using an elongated sharply cut Pasteur pipette.
7. Once a week, passage colonies enzymatically:
   1. Remove medium and wash colonies with 2 ml PBS.
   2. Remove PBS and incubate them with 0.5 ml per well of warm collagenase IV at 1 mg/ml for 10 min at 37 °C, 5% CO₂.
   3. Collect colony fragments in 2 ml new PM and centrifuge at 115 x g for 3 min.
8. Alternatively, colonies can be passaged mechanically by scraping:
   1. Remove medium and wash colonies with 2 ml PBS.
   2. Manually scrape colonies using the StemPro EZPassage roller scraper tool (Figure 1B).
   3. Collect colony fragments and centrifuge then for 3 min at 115 x g to remove the supernatant.
   4. Plate fragments on γHFF or process them for differentiation into embryoid bodies (EBs).

2. Human ESC Differentiation Protocol

1. Prepare the differentiation medium (DM) using Knockout DMEM supplemented with 2% Hyclone serum, 1.0% MEM Non-Essential Amino Acids, 1.0% L-glutamine 200 mM, 1% penicillin-streptomycin, 3.5 µl β-mercaptoethanol.
2. Remove medium and wash colonies with 2 ml PBS.
3. EB formation of colony fragments in suspension:
   1. Remove PBS and incubate them with 0.5 ml per well of warm collagenase IV at 1 mg/ml for 10 min at 37 °C, 5% CO₂.
   2. Collect colony fragments in 2 ml new DM and centrifuge at 115 x g for 3 min.
   3. Culture them in suspension in ultra-low attachment 6-well plates (2 ml per well) for 4 days (Figure 1C).
   4. Collect and plate the newly formed EBs on 0.1% gelatin-coated 24-well plates (about 3 EBs/well) (Figure 1D).
4. Alternatively, forced aggregation of single cells into EBs using the Aggrewell plate:
   1. Remove PBS and dissociate colonies into single cells using accutase (0.5 ml/well).
   2. Centrifuge and resuspend cells in DM at 1.2 x 10⁶/ml.
   3. Add 2 ml per Aggrewell chamber for 1 day (Figure 1B').
   4. Collect newly formed EBs (Figure 1C') and plate them on 0.1% gelatin-coated 24-well plates (about 3 EBs/well).
   5. Change DM every 2-3 days until the appearance of beating clusters of cardiomyocytes (15-30 days).

3. Air-liquid 3D Cultures of Beating Clusters and Labeling with HNPs

1. Identify and manually dissect clusters of beating cardiomyocytes (Figure 1D), normally appearing after 2-4 weeks of culture, using an elongated sharply cut Pasteur pipette.
2. Deposit 4 PTFE filters per insert that will be placed on a 6-well plate (Figure 1F).
3. Add 1 ml of DM medium on top of each well.
4. Add one dissected beating cluster on each PTFE filter (Figure 1E), maximum 4/well, i.e. 24 aggregates per plate (Figure 1F').
5. Change DM medium every 2-3 days.
6. To label the clusters, remove the PTFE filter containing the beating cluster and put it on 3.5 cm glass bottom dish (170 µm thick).
7. Add 1 ml of HNP at a concentration of 50 µg/ml for 30 min.

4. Non-linear Optical Imaging

1. Sample preparation. After HNP labeling (see Step 3.6), transfer either whole differentiating early hEBs or cardiac beating clusters (dissected upon contraction appearance) on PTFE filters over a 170 µm thick glass-bottom dish compatible with the working distance of high numerical aperture objectives. Alternatively, apply a direct coating of beating clusters to the glass-bottom dish pre-coated with 0.1% gelatin.
2. Transfer samples to an all-in-one microscope equipped with incubating chamber ensuring stable temperature, humidity and CO₂ control over extended periods of time.
3. After initial inspection, image the sample via wide-field imaging under white light illumination to identify structures of interest within differentiated EBs or active beating clusters that will be selected for further investigations.
4. If cell autofluorescence from NADH and SH from HNPs have to be simultaneously acquired, set a shorter laser excitation wavelength (i.e. 720 nm) to match the molecular absorption. Use one narrow band-pass spectral filter centered at half the excitation wavelength (i.e., λ = 360 ± 10 nm) to detect SH, and another one to detect autofluorescence.
5. Firstly perform a fast, low resolution, three-dimensional scan to rebuild the overall morphology of the cardiac cluster and select an image plane within the cluster volume with several visible HNPs.
6. If necessary, change the excitation wavelength freely to best match the sample's optical properties or to avoid photobleaching, photo damage and to image deeper into tissues with an IR wavelength (i.e., 790 nm) and replace the second harmonic filter accordingly (i.e., 395 nm). Optimize the settings of the laser pulse pre-compressor at the working wavelength of choice by maximizing the second harmonic signal of HNPs deposited on the sample.
7. To monitor in real time the cardiac cluster contractions, set the microscope optical scanner in the fastest mode such as resonant mode, allowing high speed acquisition of two-dimensional images.
8. Choose the settings as best compromise between image contrast and acquisition speed, such as:
   • Scan averaging: 4
   • Pixel dwell time: 0.1 µsec
   • Image rate: 3.75 frames per sec (fps)
9. Laser power is adjusted according to focal spot size and scanning speed. 50 mW (measured at the entrance of the objective) is a typical value for 0.1 µsec pixel dwell time and Plan APO 20X N.A. 0.75 objective preserving cell viability.

5. Image Analysis

1. Axial calibration procedure. Select a single HNP deposited on a bare substrate. Adjust the focus (i.e. the axial position of the nanoparticle) for maximizing the SH intensity. Vary in a controlled way the axial position of the microscope stage to obtain the calibration curve relating SH intensity as a function of the HNP offset from the focal plane. The output of this calibration procedure for the Plan APO 20X N.A. 0.75 objective is reported in Figure 4C.
2. Select HNPs present in all video frames and determine their periodic movements. This procedure can be easily automated, for example by a custom code seeking for signal maximum intensity spots in a defined region of interest and connecting them among different frames (an example code written in Matlab R2009 b using the function 'region props' of the Image Processing Toolbox is presented).
3. Assess the quantification of the out-of-plane displacements, associated with non-continuously traceable HNPs moving along the optical axis, by converting their intensity modulations throughout different frames into axial displacement using the calibration curve established at Step 5.1. Note that this procedure gives access to axial movements but cannot be used to determine the absolute direction (upwards or downwards).

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Wyniki

Prior to assessing the beating activity by confocal imaging, a careful characterization of the nonlinear optical response of the PTFE filters was performed, either alone or in the presence of HNPs at high concentration (1 mg/ml). It was ensured that: i) the bare substrate two-photon excited fluorescence is very weak and cannot prevent measuring the relevant biological samples, and ii) the SH emission from isolated HNPs can be easily acquired by imaging through the substrate in epi-detection mode (Figure 2

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Dyskusje

The application of nanotechnology to stem cell research is a relatively new but rapidly expanding field. As pointed out by various review articles on the subject, the use of nanoparticles can be applied to accomplish different research tasks, ranging from cell tracking (both in vitro and in vivo), to intracellular delivery of proteins and genes, not least the creation of biomimetic cellular environments for preferential stimulation/inhibition of specific differentiation pathways^19,20. Th...

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Materiały

Name	Company	Catalog Number	Comments
Microscope Incubator	OKO LAB	UNO package (top stage)	37 °C, 5% CO2, moisturized
Multiphoton microscope	Nikon	AR1-MP
Fast scanning, four nonphotomultiplier descanned detectors
Filters SHG and autofluorescence	Semrock	FF01-360/12-25
FF01-395/11-25
FF02-485/20-25
Microscope objectives	Nikon
CFI Plan Fluor 10X			NA 0.30, WD 16 mm
CFI Plan Apo 20X			NA 0.75, WD 1.0 mm, VC
CFI Apo 40X			NA 1.25, WD 0.18 mm λS, Nano-Crystal Coat
Rhock inhibitor	Sigma	Y-27632
Knockout DMEM	Invitrogen	10829
Knockout Serum	Invitrogen	10828
MEM Non-Essential Amino Acids	Invitrogen	1140
L-glutamine 200 mM	Invitrogen	25030
Penicillin-streptomycin	Invitrogen	15140
β-mercaptoethanol	Sigma	M7522
Collagenase IV	Gibco	17104-019
Roller scraper tool	StemPro EZPassage, Invitrogen	23181-010
StemPro Accutase	Gibco	S11105-01
Aggrewell system	StemCell Technologies	27845
Hyclone serum	Thermo Scientific	SH30070.03
Gelatin	Sigma	G9391
6-well plates	Falcon	353046
24-well plates	Nunclon	142475
Polytetrafluoroethylene (PTFE) filters	Millipore	NA76/25
Inserts	Millipore	PICM03050