2.4.1.

Animal care

Athymic male $nu∕nu$ nude and C57 mice were maintained in a barrier facility under pathogen-free conditions. All surgical procedures and intravital imaging were conducted in accordance with approve University of California, San Diego, Animal Care Program protocols, and within the guidelines of the National Institutes of Health Guide for the Care and Use of Animals.

2.4.2.

Orthotopic injection of tumor cells

The human pancreatic cancer cell lines FG, FGM, FGβ3, and XPA–1 were maintained in RPMI 1640, and stably expressed either the DSRed-2 red fluorescent protein (RFP) or green fluorescent protein (GFP). Prior to implantation into the pancreas of healthy male nude mice, cells were harvested and resuspended in serum-free RPMI at 100,000 cells per microlite. The animals were anesthetized using a 50% ketamine, 38% xylazine, and 12% maleate mixture injected intramuscularly (i.m.) at a dose of $2\mu \mathrm{l}∕\mathrm{kg}$ , and the tail of the pancreas was gently exposed. A $20\text{-}\mu \mathrm{L}$ Hamilton Syringe (Hamilton Company, Reno, Nevada) was used to inject $2\mu \mathrm{L}$ of the prepared cell suspension into the pancreatic tail. The peritoneum and skin were then closed using 6-0 ethibond sutures (Ethicon, Somerville, New Jersey).

2.4.3.

Imaging of the pancreas

After the implanted tumor cells were allowed to grow for $7\text{to}14\text{days}$ , mice were again fully anesthetized, kept warm, and the tail of the pancreas and spleen were gently exposed with careful attention paid to maintaining meticulous hemostasis throughout the dissection. The pancreatic tail with the tumor was then stabilized away from the animal’s body between a glass slide and cover slip, and maintained in a moist environment via repeated irrigation with sterile saline. A saline-filled clear glass trough was placed over the pancreas and a dipping lens was inserted into the saline for imaging.

2.4.4.

Preparation of T-cells for lymph node inoculation

OT-II TCR transgenic (Tg) mice were bred to the CD45.1 congenic background. The OT-II TCR is specific for a chicken ovalbumin peptide 323-339 $\left(\mathrm{pOVA}\right)∕\mathrm{I}\text{-}{\mathrm{A}}^{\mathrm{b}}$ complex. Wild-type C57BL/6 mice ( $6\text{to}8\text{weeks}$ of age) were purchased from Charles River Laboratories (Frederick, Maryland). Donor OT-II CD4 T cells from the secondary lymphoid tissues (axillary, brachial, cervical, inguinal, mesenteric lymph nodes, and spleen) were purified by CD4 T cell negative selection using magnetic microbeads (Miltenyi Biotec, Auburn, California). The purified cells ( $>94\%$ pure) were labeled with $2\text{-}\mathrm{mM}$ 5,6-carboxyfluorescein diacetate succinimyl ester (CFSE, Molecular Probes, Eugene, Oregon) with 0.1% BSA for $10\min$ at $37°\mathrm{C}$ and injected into the tail vein at $\sim 5\times {10}^6$ cells per C57BL/6 recipient mouse.

2.4.5.

Imaging of lymph nodes

Mice were euthanized by $\mathrm{C}{\mathrm{O}}_2$ asphyxiation and inguinal lymph nodes were removed for microscopy. Lymph nodes were secured on the bottom of a $30\text{-}\mathrm{mm}$ petri dish with a thin film of VetBond (3M) and maintained at $37°\mathrm{C}$ by perfusing the chamber with warm PBS. Perfusion nozzles and a temperature thermistor probe (VWR® Snap-In Module Thermometer, VWR, West Chester, Pennsylvania) were secured in the petri dish; PBS was recirculated and maintained at $37°\mathrm{C}$ with a water bath. A $20\times$ water dipping lens was advanced into the PBS over the lymph node for imaging.

3.1.1.

Confirmation of 2-P imaging

Prior to engaging in biological imaging, we conducted some simple tests and imaging exercises to ensure that the microscope was operating satisfactorily as a 2-P instrument. Two-photon excitation is a quadratic process, very dependent on incident photon flux, as two excitation photons are needed to cause a single emission. In contrast, single photon excitation is a linear process. Accordingly, a fluorescent plastic slide was imaged with escalating doses of laser power with both confocal and multiphoton microscopes. As indicated by Fig. 3a, the confocal logarithmic plot of laser power versus emitted light intensity did yield a line with a slope of close to one $(\sim 0.9)$ , as predicted for a confocal system.²⁴ The multiphoton plot yielded a slope of 2 [Fig. 3b], which is expected for the 2-P quadratic relationship between emitted fluorescence intensity and excitation beam intensity.^{24, 25} These data demonstrate that our microscope was in fact operating properly as a two-photon instrument.²⁴

Fig. 3

Both figure panels are log—log plots of average laser intensity versus emitted fluorescence intensity. The line depicting confocal data in (a) has a slope of 0.9, while the multiphoton data in (b) is has a slope of 2, a quadratic relationship.

3.1.2.

Imaging depth performance

The ability of the multiphoton instrument to penetrate an agar-milk gel phantom impregnated with $0.4\text{-}\mu \mathrm{m}$ fluorescent beads was evaluated using a $20\times$ dry lens and a $20\times$ dipping lens. For comparison the same $20\times$ dry lens was fitted to a confocal microscope and tested with the same sample of fluorescent agar-milk gel standard. Before confocal and 2-P imaging of the gel standard, however, the optical attenuation (absorption and scattering) characteristics of the phantom were compared with freshly extracted mouse brain tissue. Mouse brain was used as the biological comparison for the gel because its composition is relatively consistent, and this tissue has been extensively imaged with 2-P systems. Hence, such a biological reference for the agar-milk gel standard provides some indication of how a 2-P system might perform in general. Tumor tissue, on the other hand, is highly heterogenous and variable, even between implanted tumors of the same line.

Table 1 indicates the attenuation coefficient for the gel standard and mouse brain tissue with the light detector at various angles from the incident laser beam. The brain had a higher coefficient of attenuation $\left(\alpha \right)$ , $5.8{\mathrm{cm}}^{-1}$ versus $4.5{\mathrm{cm}}^{-1}$ , but for the scattering conditions, the $\alpha$ values were closer. Importantly, in the backscattering condition where absorption would be expected to contribute less to attenuation, the raw values and the attenuation coefficient between the gel and brain were comparatively close, differing by only 12%. Therefore, the agar-milk gel standard did approximately mimic the scattering characteristics of brain tissue. In this context it is significant that with the near IR, where many confocal and all 2-P measurements are made, absorption is much less of a factor than scattering.²⁶ Hence the gel phantom should suffice for assessing the performance of a 2-P instrument.

Table 1

Attenuation of 532-nm 5-mW laser light by a gel phantom and mouse brain.

The multiphoton microscope was able to acquire emitted light from deep within the gel standard. Figure 4 is a plot of average grayscale intensity of light emitted from the gel-imbedded fluorescent microspheres versus depth. The data reveal that the signal intensity for the confocal dropped off immediately and steeply after $50\text{-}\mu \mathrm{m}$ imaging depth, while the same $10\times$ dry lens on the 2-P instrument acquired emitted light approximately three-fold deeper, almost to $400\mu \mathrm{m}$ with relatively little signal loss. The $20\times$ dipping lens and the $20\times$ dry lens, when mounted on the 2-P instrument, exhibited similar performance. However, the dipping lens was able to acquire images of fluorescent beads to about $750\text{-}\text{to}800\text{-}\mu \mathrm{m}$ depth, albeit with diminished signal intensity. The 2-P intensity increase, observed between 50 and $150\mu \mathrm{m}$ , is interesting. It is possible that this effect may be due to the redirecting of emitted photons by scattering. These photons enter the PMT, resulting in an increased signal. This could be an advantage of nondescanned imaging, as a descanned system may allow the scattered photons to diverge before entering the PMT.

Fig. 4

A plot of average grayscale intensity versus sample imaging depth. The confocal signal intensity, using a $20\times$ dry lens, fell steeply after $50\text{-}\mu \mathrm{m}$ imaging depth. The same $20\times$ dry lens on the 2-P instrument penetrated the sample approximately three-fold deeper, almost to $400\mu \mathrm{m}$ . The $20\times$ dipping lens and the $20\times$ dry lens, when mounted on the 2-P instrument, exhibited similar performance, although the dipping lens was able to acquire images of fluorescent beads to about $750\mu \mathrm{m}$ depth.

To obtain additional evidence that a small 2-P excitation volume developed at increased sample depth along with retention of signal quality, a 2-D Fourier transform (2-D FFT) was performed on the images acquired at different sample depths. Note from Fig. 5a that confocal image power spectra contained a spectrum of frequencies for the slide surface with a central peak and side lobes (arrows in figure). The emission spectrum of the slide was measured independently and found to have a peak and broad shoulder and tail, encompassing nearly $200\mathrm{nm}$ . Therefore, a range of frequencies is expected in the power spectrum. Figure 5b is the same plot for image data acquired at $100\text{-}\mu \mathrm{m}$ depth, and there was considerable contraction of the frequency profile with a disappearance of the side lobes (arrows). The comparable multiphoton data, shown in Figs. 5c and 5d, reveal a sharply defined peak (arrows) with distinct frequency lobes (white arrows) both at the surface and also at $100\mu \mathrm{m}$ . The multiphoton power spectra remained relatively constant regardless of sample imaging depth, while the initial confocal profile was lost at the deeper imaging position.

Fig. 5

The power spectra (square of Fourier transform) of the $60\times$ images taken of a comparatively broad emission spectrum (approximately $200\mathrm{nm}$ ) red fluorescent slide at its surface and at a focal depth of $100\mu \mathrm{m}$ are shown. The vertical axis denotes relative power while the two horizontal axes represent spatial frequency. (a) and (b) show the surface and $100\text{-}\mu \mathrm{m}$ spectra, respectively, for confocal microscope images. Note the peak and frequency side lobes, indicated by white arrows. (c) and (d) show the same for the multiphoton microscope. Note that the multiphoton spectra remain constant regardless of imaging depth, with no loss of side lobes (arrows), while the confocal spectra reveal a loss of information.

3.1.3.

Light transmission of long-working-distance objectives

The microscope objectives used with the rebuilt 2-P microscope were long-working-distance lenses intended for intravital and wet biological work. However, a significant number of microscope objectives are not designed specifically for use with a Ti-sapphire laser. Therefore, we sought to determine the approximate transmission characteristics of the lenses, as significantly reduced transmission has been demonstrated to cause detrimental broadening of the laser pulse.^{27, 28} Such distortion of the original beam from the sharp temporal Gaussian can markedly reduce 2-P efficiency, depth penetration, and image quality.¹⁶ The transmission for all lenses tested remained relatively constant between 750, 800, and $920\mathrm{nm}$ and the $10\times$ , $20\times$ , and $40\times$ lenses exhibited good IR transmission,¹⁵ in excess of 75%, at $800\mathrm{nm}$ (Table 2 ). As expected, the $60\times$ lens exhibited acceptable but substantially lower IR transmission, most likely because of significant overfilling of the back aperture of the objective. The loss of laser power through the scanhead alone was about 25%, and with the scanhead and the long-pass dichroic mirror combined, the loss was about 36% of the incident laser power. This indicates that light emitted from the sample would be considerably attenuated if returned through the dichroic mirror and the scanhead. The loss in signal would be further increased by divergence of emitted light from the sample traveling to the scanning mirrors (descanning). These observations are consistent with other reports that indicate that operating a multiphoton microscope in descanned mode leads to a significant loss of incident light signal.^{11, 12, 22, 25} Therefore, the final design of the microscope described in the present report incorporated a nondescanned configuration to optimize signal to noise.

Table 2

Transmission of IR delivered by 120-fs pulsed Ti-sapphire Gaussian laser beam expanded to 4-mm with a 500-mm FL lens and passed through a half-wave plate, polarizing beamsplitter, and Nikon CS-1 scanhead. The percent transmission is expressed as intensity of light at the sample plane divided by intensity of light entering the back aperture of the objective. Each value is the mean of three readings.

3.2.1.

Intravital image quality with live subjects

Using a range of magnifications with the 2-P microscope and the OV100, it was possible to capture the considerable extent of the vasculature associated with the tumor, including the characteristic tortuous tumor blood vessels. The high resolution imaging afforded with the multiphoton microscope, at multiple magnification settings, allowed individual cell interactions with blood vessels to be imaged with a high degree of detail [Figs. 6a and 6b ].

Fig. 6

Multiphoton images taken at (a) $40\times$ and (b) $60\times$ . (a) shows green-labeled (GFP) human pancreatic (FG-RFP) cells growing in the living pancreas of the nu/nu mouse. Tumor blood vessels can be seen in red $(\text{bar}=100\mu \mathrm{m})$ . The image in (b) is digitally zoomed showing details of XPA-1–RFP pancreatic tumor cells that appear red. The vessels in (b) were labeled with IV injected FITC-lectin. Note the engagement of the cells with the blood vessel (B $\text{bar}=100\mu \mathrm{m}$ ). Cellular detail in (b) is excellent, considering that this image was acquired between 75- and $100\text{-}\mu \mathrm{m}$ solid-tumor depth within the pancreas of a live animal. (Color online only)

We found that the best imaging of the tumor in terms of detail and depth penetration was accomplished with long-working-distance objectives ( $2\text{-}\mathrm{mm}$ WD), mainly water dipping lenses. To maintain an adequate water layer between the objective and the tissue, an optical trough had to be fabricated. The sides of the trough were machined from stainless steel, and a $0.1\text{-}\mathrm{mm}$ -thick glass slide was fixed to the steel frame with RTV silicone. However, the dipping lenses were not designed to compensate for spherical aberration induced by light refraction by the coverslip. Therefore, to minimize these effects, the coverslips were thin $\left(0.1\mathrm{mm}\right)$ and made from low refractive index plastic. The trough was used as a coverslip and not filled with fluid for the long-working-distance $10\times$ dry lens. When features of interest were acquired, the microscope stage was held stationary, the $20\times$ and $40\times$ lenses were moved into place, and the trough was filled with PBS. Higher magnification 2-P imaging proved quite feasible with the externalized pancreas preparation. Figure 6b is a digitally magnified $60\times$ image of individual cells engaging adjacent blood vessels.

3.2.2.

High resolution long-working-distance multiphoton imaging complements other imaging platforms

Multiphoton imaging of the developing tumors in whole, live mice demonstrates very high resolution of the tumor cell architecture (Figs. 6 and 7 ). The multiphoton images revealed cell morphology, while the OV100 showed an overview of blood vessel development and tumor growth.

Fig. 7

An example of the feasibility of dual color labeling with multiphoton systems, which also illustrates how the multiphoton and OV100 imaging systems offer complementary information about tumor morphology in live mice. Animals inoculated with a mixture of cells expressing either dsRed2 or GFP into the pancreas were imaged using both the Olympus OV100 (a) and (b) or (c) the multiphoton microscope. The OV100 facilitates imaging the entire tumor and gives information regarding the position of the different cell populations within the tumor as a whole, while the multiphoton microscope $(40\times )$ gives highly detailed images of the in vivo interactions of the different cell populations within the tumor parenchyma. Moreover, the 2-P system was able to effectively discriminate between the two colors. The OV100 scale bars represent (a) $2\mathrm{mm}$ and (b) $1\mathrm{mm}$ , and the 2-P scale bar denotes approximately $125\mu \mathrm{m}$ . (Color online only.)

Low and high magnification images acquired with the OV100 variable magnification fluorescence system show the general position and size of the pancreatic tumor in the living mouse. The multiphoton, however, provides imaging of cellular extensions (Figs. 6 and 7) and details relating to tumor vessels, such as the entry of cells into vessels. The data obtained show the feasibility of multiphoton imaging, with the custom rebuilt microscope, of a mixed population of cells that stably express either GFP or dsRed fluorophores (Fig. 7). The color cross talk between channels can be minimized by a judicious selection of color filters, although more expensive options, such a tunable liquid crystal filters are available.²⁹ We were able to significantly reduce cross talk in our multiphoton system using a combination of filters that included an extended long pass, laser-grade long-pass dichroic mirror (reflects $400\text{to}680\mathrm{nm}$ , transmits $715\text{to}1064\mathrm{nm}$ ), a 2-P emission splitter (reflects $510\pm 50$ , transmits 605/70), a GFP filter (transmits $510\pm 50\mathrm{nm}$ ), and an m-cherry filter (transmits $645\pm 65\mathrm{nm}$ ).

3.2.3.

Imaging of labeled T-cells within lymph nodes

Lymph nodes are a comparatively dense tissue and thus it is a challenge to image the interior of these structures. Our instrument was able to image numerous T-cells at $200\text{to}300\mu \mathrm{m}$ , and even at $500\mu \mathrm{m}$ , which was completely through the main thickness of the node [Figs. 8a and 8b ]. Nuclei and cellular structures are not visible with the kind of fluorescent labeling used for these experiments, but cellular extensions were identifiable when the $225\text{-}\mu \mathrm{m}$ -deep $20\times$ images were digitally magnified [Fig. 8c]. In comparison, a commercially available descanned system was used to image precisely the same type of lymph node preparation, but was able to obtain images only to $100\mu \mathrm{m}$ depth, and detected fewer cells [Fig. 8d]. Moreover, the stage on the descanned microscope accommodated our lymph node physiology hardware only with difficulty.

Fig. 8

(a) and (b) are, respectively, a FN-1 nondescanned 2-P image of fluorescently labeled T-cells $225\mu \mathrm{m}$ deep within a murine lymph node, and a similar image taken at $500\mu \mathrm{m}$ (scale $\text{bars}=100\mu \mathrm{m}$ ). (c) is the digitally-magnified $225\text{-}\mu \mathrm{m}$ -deep $20\times$ image showing individual cells with protrusions (arrow, scale $\text{bar}=20\mu \mathrm{m}$ ). (d) shows a comparable image acquired with a commercially available descanned 2-P system. The imaging depth is approximately $100\mu \mathrm{m}$ . Note that fewer cells can be seen and the image quality is inferior to that of our non-descanned FN-1 2-P system (scale $\text{bar}=100\mu \mathrm{m}$ ).