Coverslips for hydrogels deposition and polymerization
Bottom coverslips (Ø15 mm, Thermo Scientific) were sonicated in acetone, subsequently rinsed with dH2O, and dried. Afterward, they were placed in a vacuum desiccator for 1 h and 3-aminopropyltriethoxysilane (APTES, Sigma-Aldrich) vapor deposition occurred. Then, the slides were immersed in 0.5% glutaraldehyde (GA, Sigma-Aldrich) in deionized water for an hour and dried. Top coverslips (Ø22 mm, Thermo Scientific) were coated with 5% SurfaSil Solution (Sigma-Aldrich) in acetone for 10 s and subsequently rinsed in acetone and methanol and dried.
Polyacrylamide gels
Stock solutions of 40% acrylamide (Sigma-Aldrich) and 2% bis-acrylamide (Sigma-Aldrich) prepared in dH2O were used to make polyacrylamide gel (PA) precursor solutions. Polyacrylamide water solutions (1 ml total volume) with final acrylamide concentration of 5% and 7% were prepared by mixing 125 μl and 175 μl of acrylamide precursor solution with 200 μl of bis-acrylamide (bis-A) precursor solution (0.4%), respectively. Before crosslinking, initiator (10 μl of 10% ammonium persulfate water solution) and accelerator (1.5 μl of tetramethylethylenediamine (TEMED, Fisher Scientific) were added to the polyacrylamide solutions and degassed in a vacuum desiccator. Then, after gentle mixing with the pipette, 60 μl drop of the final solution was placed on a bottom coverslip and covered with a SurfaSil modified coverslip, which was removed after 20 min polymerization time. Polyacrylamide gels were placed in dH2O and stored at a temperature of 4 °C prior to examination. Two samples per each case were prepared in one batch for the AFM measurements (in total 30–40 elasticity maps were recorded per each case). This approach resulted from the fact that there might be discrepancies in the mechanical properties of PA gels among different batches, although the same preparation protocol is used (Denisin and Pruitt 2016). The reason for choosing these acrylamide concentrations was to obtain gel samples characterized by a similar range of Young’s modulus as cells are. The thickness of PA gel samples was 1–2 mm.
Cell cultures
Two human cell lines were chosen for the study, i.e., non-malignant cell cancer of ureter (HCV29, Institute of Experimental Therapy, Wrocław, Poland) and urinary bladder carcinoma cell line (HT1376, grade III, ATCC, LGC Standards). HCV29 cells were cultured in RPMI-1640 (Sigma) supplemented with 10% fetal bovine serum (FBS, Sigma) and HT1376 cell line was cultured in Eagle’s medium (EMEM, LGC Standards) supplemented with 10% FBS (LGC Standards). The cells were grown on glass coverslips placed inside the polystyrene Petri dish at 37 °C in 95% air/5% CO2 atmosphere. The relative humidity was kept above 98%. For elasticity maps, HCV29 cells were grown in the tissue culture dish (Ø34 mm, TPP®). The AFM measurements were carried out after 48 h culture, in the corresponding media, at room temperature. With each cantilever type, ~ 30 individual cells were measured. The height of the cells within the nuclear region was about 7–10 μ.
AFM-based force spectroscopy
Force spectroscopy measurements were conducted using XE120 AFM (Park Systems, South Korea) equipped with a liquid cell setup. Various silicon nitride cantilevers with mounted probing tips of diverse geometries were employed. They can be divided into three groups, namely, (i) symmetric pyramidal probes (MSCT-AUH, Veeco; customized PNP, Nanosensors; OTR4, Bruker); (ii) non-symmetric pyramidal probes (MSNL&MLCT, Bruker); and (iii) a pyrex-nitride colloidal probes (sQube, CP-PNP-SiO-C-5, NanoAndMore). Nominal values of half open-angles, cantilever spring constants, and radii of curvature are included in Table 1. Spring constants of the cantilevers were calibrated using the thermal noise method in the air (Schillers et al. 2017). Photodetector sensitivity, i.e., the inverse of the slope, was obtained by fitting a line to the slope of the force curve acquired on the stiff substrate (glass or Petri dish). Measurements were conducted on PA gels and cells. Both cells and PA gels were measured with the same cantilevers. Force curves were recorded within a scan area of 6 μm × 6 μm, within which a grid of 8 × 8 points was set. In total, 64 force curves were acquired (in the case of cells, a nuclear region was probed). The force–distance curves were recorded at an approach velocity of 8 μm/s, the maximum force of 7 nN, and a force curve length of 4 μm.
Table 1 Characteristic parameters of one set of AFM probes used in the experiment Young’s modulus determination
Individual force curve is a relation between a cantilever deflection and a relative scanner position. The deflection of the cantilever is converted into a force by multiplying it by cantilever spring constant. An indentation depth is obtained by subtracting a calibration curve recorded on a stiff non-deformable surface (Fig. 1a). This requires the knowledge of the position of the contact point. In this study, we used eye inspection convoluted with fitting a horizontal line to the baseline; therefore, indentations lower than 100 nm are not considered during the analysis. The obtained force-versus-indentation curves were then fitted to the Hertz model (Lekka et al. 1999; Schillers et al. 2017). In our study, AFM probes with four-sided geometry were approximated by a cone. In such a case, the relation between the load force (F) and the indentation depth (δ) is
$$F\left( \delta \right) = \frac{2}{\pi }\tan \left( \alpha \right) E_{{{\text{eff}}}} \delta^{2} ,$$
(1)
where α is the open-angle of the cone. For a sphere of radius R, the following equation was applied:
$$F\left( \delta \right) = \frac{4}{3}\sqrt R E_{{{\text{eff}}}} \delta^{\frac{3}{2}} .$$
(2)
Eeff is the reduced Young’s modulus given by
$$\frac{1}{{E_{{{\text{eff}}}} }} = \frac{{1 - \mu_{{{\text{tip}}}}^{2} }}{{E_{{{\text{tip}}}} }} + \frac{{1 - \mu_{{{\text{sample}}}}^{2} }}{{E_{{{\text{sample}}}} }}.$$
(3)
When Esample << Etip, the following relationship can be obtained:
$$E_{{{\text{eff}}}} = \frac{{E_{{{\text{sample}}}} }}{{1 - \mu_{{{\text{sample}}}}^{2} }},$$
(4)
where µsample and µtip are Poisson’s ratio related to the compressibility of the sample and indenting tip.
In our analysis, we set Poisson’s ratio to 0.5 for both polyacrylamide gels and cells assuming that these samples are incompressible. The apparent Young’s modulus was calculated by fitting a Gauss function to moduli distributions (Fig. 1b presents an exemplary histogram obtained for a 5% PA sample measured with OTR4 AFM probe). The center of the distribution denotes the mean value, while the standard deviation is determined from the distribution width. Figure 1c shows the variability of elastic modulus present within the recorded scan area of 6 μ.
Obtaining the relation between Young’s modulus and indentation depths
In our analysis, we calculated the Young’s modulus as a function of indentation depth varied within a range of 100–700 nm, with a step of 50 nm. Indentation depth below 100 nm was omitted to a possible effect of a misdefined contact point between a tip and a sample surface while larger indentations (above 700 nm might be influenced by the underlying substrate observed as an increase of the modulus values). Starting from the contact point, the Hertz model was fitted to a fragment of the force curve corresponding to a specific indentation (Fig. 1d). The shape of the indenting tip defines the relationship between a load force and indentation depth. The cone (or pyramid) predicts F = B·δ2, while for the sphere (or paraboloid), F = A·δ3/2. Both A and B can be re-written in a form c·E, where c is the constant including all the geometrical information together with the Poisson’s ratio and E is Young’s modulus (Weber et al. 2019). Frequently, real data recorded during cell indentation rarely fully follow these relations. To elaborate more precisely how the divergence of fitting data with both relations affects the fitting parameters, experimental points (δn, Fn) in the force–indentation curve can be assumed to follow: Fn = A·δn2−ε and δn = n·δ0, where δ0 is the indentation difference between adjacent points, n is the number of points, yn is the load force corresponding to the indentation δn, A is the fitting parameter proportional to Young’s modulus, and ε is the value expressing how much the cone (or pyramid) approximation differs from the experimental curve. The fitted parameter B can be calculated from Fn = B·δn2. For N experimental points recorded up to chosen maximum indentation:
$$B = A \cdot \delta_{0}^{ - \varepsilon } \cdot \frac{{\mathop \sum \nolimits_{n = 0}^{N} \delta n^{4 - \varepsilon } }}{{\mathop \sum \nolimits_{n = 0}^{N} \delta \delta n^{4} }}.$$
(5)
Thus, the larger N (i.e. fitting data for larger indentation) will generate the lower fitted B value (Fig. 1e). Analogously, in the case of spherical (or paraboloidal) assumption of the indenter, the fitted parameter C follows the relation:
$$C = A \cdot \delta_{0}^{ - \varepsilon } \cdot \frac{{\mathop \sum \nolimits_{n = 0}^{N} \delta n^{3 - \varepsilon } }}{{\mathop \sum \nolimits_{n = 0}^{N} \delta n^{3} }}.$$
(6)
The C value increases with the data size to be fitted (for larger N, the higher fitted C is obtained, Fig. 1e). Depending on the theoretical model, the divergence ε was calculated. It shows how much the obtained data differs from the assumed theoretical model (cone or paraboloid). In our case, the choosing a cone as an approximation of the AFM tip shape induces its smaller deviations (Fig. 1f).
Elasticity mapping
Elasticity maps of cells were acquired with the use of JPK AFM equipped with NanoWizard 4 head by employing a classical force volume mode. Rectangular cantilever ORC8 with nominal spring constant k = 0.05 N/m, nominal resonance frequency fnom = 18 kHz, opening half-angle α = 36°, and nominal tip radius of 15 nm were used. We choose ORC8 instead of OTR4 as these cantilevers seems to be more stable when long force volume measurements are conducted. The AFM tip shape of OTR4 and ORC8 is the same. Due to cell heterogeneity, the size of maps varied between 45 µm × 45 µm and 50 μm × 50 μm, but, always, a size of a single-pixel kept being 1 µm2. Elasticity maps were recorded with the approach/retract speed of 8 μm/s and load force 10 nN. The time needed to record a single map varied from 45 to 70 min.
Scanning electron microscopy
The SEM images of the used cantilevers were recorded using the FEI Quanta FEG-SEM in low vacuum conditions. The electron beam was operating at 5 kV accelerating voltage, 5 nA current, and a working distance of about 5 mm. Images of AFM tips were captured using the secondary electrons signal for only one set of cantilevers (one image per one cantilever).
Statistical analysis
All calculations and statistical analyses were performed using OriginPro 2015. Data are represented as the mean ± standard error obtained from all measurements. Statistical significance was evaluated using two-sample Student’s t test for testing the equality of the means between two populations, assuming various numbers of samples analyzed (using OriginPro 2015). All statistical tests were two-sided and p values of < 0.05 were considered statistically significant.