Fluorescence microscopy has profoundly changed cell and molecular biology studies by permitting tagged gene products to be followed as they function and interact. The ability of a fluorescent dye to absorb and emit light of different wavelengths allows it to generate startling contrast that, in the best cases, can permit single molecule detection and tracking. However, in many experimental settings, fluorescent probes fall short of their potential due to dye bleaching, dye signal saturation, and tissue autofluorescence. Here, we demonstrate that second harmonic generating (SHG) nanoprobes can be used for in vivo imaging, circumventing many of the limitations of classical fluorescence probes. Under intense illumination, such as at the focus of a laser-scanning microscope, these SHG nanocrystals convert two photons into one photon of half the wavelength; thus, when imaged by conventional two-photon microscopy, SHG nanoprobes appear to generate a signal with an inverse Stokes shift like a fluorescent dye, but with a narrower emission. Unlike commonly used fluorescent probes, SHG nanoprobes neither bleach nor blink, and the signal they generate does not saturate with increasing illumination intensity. The resulting contrast and detectability of SHG nanoprobes provide unique advantages for molecular imaging of living cells and tissues

Billinton

Bruchez Jr.

Campagnola

Chan

D. Wu

Dahan

Datta

Denk

Dickson

Fitzpatrick

Hadjantonakis

Hsieh

Huang

J. Maloney

Larson

Lippincott-Schwartz

Madsen

Michler

P. Pantazis

Pantazis

S. E. Fraser

Shaner

Stollberg

Tromberg

Wang

Weissleder

Xing

English

PubMed

Pantazis, Periklis

Maloney, James

Wu, David

Fraser, Scott E.

Caltech Authors - Main

Second harmonic generating (SHG) nanoprobes for in vivo imaging

P.  Pantazis

Crossref

Supporting Information
Pantazis et al. 10.1073/pnas.1004748107
SI Text
SI Materials and Methods. Second harmonic generating (SHG) signal
profile analysis. SHG signal profiles of SHG nanocrystals (n ≥ 5
for each nonlinear material) covering the spectral range from
380 to 720 nm were recorded using the META detector of the
Zeiss LSM 510NLO microscope setup by tuning the wavelength
from 780 to 970 nm. The background measured in a random
region of the gel without SHG nanocrystals was subtracted. To
make the results insensitive to changes in laser power or pulse
width, the data have been corrected according to the following
equation that is derived from the nonlinear nature of SHG:
SHGSignal ∝ ðPmÞ2
T
τ
;
where Pm is the mean laser power after the microscope objective
for each wavelength, τ is the previously measured pulse width (1),
and T is the pulse repetition rate (80MHz). Obtained SHG signal
values were normalized by setting the highest signal value to 100.
Control experiments of BaTiO3 nanoparticle characterization. For
SHG nanoparticle characterization (blinking property compari-
son and signal saturation comparison), we controlled several
conditions to study presumably individual nanocrystals. First,
the sample was ultrasonicated and nanofiltered. The presence
of isolated nanocrystals was confirmed (see Fig. S2A) using
atomic force microscopy in the tapping mode (AFM, Digital In-
struments). A 2 μL drop of sample was applied to the surface of
freshly cleaved mica and immediately analyzed. Second, SHG so-
lutions were immobilized in 20% polyacrylamide gel to avoid
clustering after nanofiltering. In addition, the weakest SHG sig-
nal intensities of BaTiO3 were chosen for comparison to quantum
dots (QDs) from “flatfielded” images, where spatial aberrations
in illumination and viewing optics, and in detector sensitivity,
were corrected as previously described (2) to rule out systematic
deviations in sensitivity over the spatial field of view. Briefly,
corrections were performed by the use of three “flatfield” images
gathered in the absence of nanocrystals using comparable excita-
tion and detection settings. One image was taken with the light
path closed (detection noise only), whereas the other two were
scans of lowandhigh concentrations (125 μg∕mLand675 μg∕mL)
of 10,000 MW Dextran-Cascade blue (Invitrogen Corp.).
Acquired data were used to insure that illumination and detector
settings were such that observations were in the linear range of the
SHG nanoparticle detection and characterization (see Fig. S2B).
Once we determined that we were imaging SHG nanocrystals
in a linear range, a custom Matlab script was used to segment the
SHG signal from gel-immobilized nanocrystal. After background
subtraction, we integrated the SHG signal in the segmented areas
corresponding to a single diffraction-limited spot. As previously
described (3), the experimental distribution ρðIÞ of the SHG
intensities I ðcounts∕pixelÞ was fitted by a sum of Gaussians:
ρðIÞ ¼∑
2
i¼1
Ai exp

−
ðI − μiÞ2
2σ2i

;
where μ is the mean, σi is the standard deviation, and Ai the am-
plitude. We chose to fit the distribution to two Gaussians by eye.
The experimental data indicated very good agreement with the
theoretical sum of Gaussians (R2 ¼ 0.89, see Fig. S2C). Given
the AFM data, the first and major peak suggests the presence
of single BaTiO3 nanocrystals.
In Vivo BaTiO3 Nanocrystal Injection and Imaging. Up to 50 fmol of
ultrasonicated and nanofiltered BaTiO3 nanocrystals were in-
jected as previously described (4). For ubiquitous SHG signal pre-
sence, BaTiO3 nanocrystals were injected into the yolk of either
zygote/one-cell stage wild-type embryos (see Fig. 4) or mutant
embryos of the cls line (5), which has fewer iridophores (see
Fig. S4 A and B and Movie S3). Embryos were raised at 28 °C
in 30% Danieau solution (4). The injected embryos developed
indistinguishably from uninjected counterparts (n ¼ 600). Prior
to SHG imaging, zebrafish were anesthetized with 0.015% tri-
caine methanesulfonate in 30% Danieau solution. Cell mem-
branes were dyed with the vital counterstain BODIPY TR
methyl ester (Invitrogen Corp.). Specimens were oriented in
1% agarose molds as previously described (6). Live images of
SHG injected zebrafish were obtained with an LD C-APO 40 ×
∕1.1 objective on a Zeiss 510NLO microscope setup. For three-
channel confocal image acquisition, a femtosecond pulsed laser
tuned to 820 nm (for imaging endogenous SHG as well as for
BaTiO3 nanocrystals) and the 543 nm He/Ne laser line (for ima-
ging BODIPY TR methyl ester) were used sequentially. Endo-
genous SHG detection was performed in transdirection using a
HQ405∕40M emission filter (Chroma Technology Corp.).
BaTiO3 nanocrystals detection was performed in both transdirec-
tion (see above) as well as in epidirection using a BP390-465IR
emission filter. A mode-locked infrared laser line at 820 nm from
a Ti∷Sapphire laser (Coherent, Inc.) with an average laser power
of at least 5 mWafter the objective (for single BaTiO3 nanocrys-
tals in tissue) and at least 50 mW after the objective (for endo-
genous SHG) was used, respectively. Nanocrystals of this size—
comparable to the size range of water-soluble QDs—often
formed clusters over time requiring lower intensities.
BaTiO3 nanocrystal imaging in mammalian tail tendon.Collagen, the
main fibrous component of tendon, cartilage, skin, etc., has been
previously shown to display a high SHG efficiency (7). In addition
to imaging BaTiO3 nanocrystals within zebrafish muscle tissue,
where arrays of myosin provide endogenous SHG contrast, we
compared achievable SHG signal intensities of BaTiO3 nanocrys-
tals to collagen within a mouse tail tendon, a tissue with large
collagen deposits of high regularity. Ultrasonicated and nanofil-
tered BaTiO3 nanoparticles were injected in mouse tail slices of
2–3 mm thickness. The injected tissue slices were oriented in 1%
agarose. Images of SHG injected mouse tail tendon were
obtained with an long-distance correction ring apochromat objec-
tive (LD C-APO) 40 x/1.1 objective on a Zeiss 510NLO micro-
scope setup. A femtosecond pulsed laser tuned to 850 nm for
imaging endogenous SHG as well as for BaTiO3 nanocrystals
was used. SHG signal detection was performed in this case in epi-
direction. Due to multiple tissue scattering and the fact that the
wavelength range we employ for exciting and collecting SHG is in
the Rayleigh scattering regime, initially forward-directed endo-
genous SHG from collagen is rerouted into the backward direc-
tion. This approach of endogenous SHG imaging comes with its
limitations: (i) significant SHG signal reduction, because back-
scattered signal represents only a small fraction of total endogen-
ous SHG, (ii) loss of SHG coherence when the SHG photon’s
travel distance before scattering (the scattering length) is smaller
than the active SHG volume dimensions, and (iii) high levels of
absorption of SHG photons due to the fact that SHG photons
must travel a long average pathlength due to multiple tissue back-
scattering events before reaching the detector. However, SHG
nanoprobe imaging does not rely on backscattering with its
Pantazis et al. www.pnas.org/cgi/doi/10.1073/pnas.1004748107 1 of 7
above-mentioned limitations for endogenous SHG. On the con-
trary, the number of detectable photons is effectively increased
because a fraction of the multidirectional SHG signal of BaTiO3
is now rerouted into the backward direction.
Long-term photostability of BaTiO3/Dextran-Alexa546 in vivo. For
SHG/Alexa546 signal presence in a subpopulation of cells, single
cell coinjections of BaTiO3 nanoparticles and 10,000 MW Dex-
tran-Alexa546 (Invitrogen Corp.) were performed at the 32-cell
stage and imaged at the dome stage of zebrafish embryos. Speci-
mens were oriented in 1% agarose molds as previously described
(6). Live images of SHG injected zebrafish embryos were ob-
tained with a LD C-APO 40 x/1.1 objective on a Zeiss 510NLO
microscope setup. For two-channel confocal image acquisition, a
femtosecond pulsed laser tuned to 820 nm (for imaging SHG na-
nocrystals) and the 543 nm He/Ne laser line (for imaging coin-
jected Dextran-Alexa546) were used sequentially. Note that
nanocrystals present in cells form to some extent clusters over
time due to anomalous subdiffusion (8), commonly observed also
for other particles of this size range like water-soluble QDs.
Immunostaining Dechorionated 24 hpf zebrafish embryos were
fixed using 4% paraformaldehyde (PFA) in PBS for 2 h at room
temperature. After a brief wash with PBS, the PFA-fixed zebra-
fish embryos were embedded in 4% agarose, sectioned using the
Vibratome Series 1000 (The Vibratome Co.). The specimens
were subsequently permeabilized in PBST (PBS with 0.1% Triton
X100) for 1 h. The tissue was then blocked in PBSTB (PBSTwith
0.5% BSA) overnight at 4 ºC. After blocking, the samples were
incubated with primary antibodies diluted in PBSTB for 2 h at
room temperature. Immunostainings were performed using
mouse anti-Dystrophin (MANDRA1, 7A10, Hybridoma Bank)
at a dilution of 1∶500. Unbound primary antibody was removed
by three washes with PBST. Subsequently, specimens were incu-
bated with the secondary antibody diluted in PBSTB for 2 h. Im-
munostainings were performed with 90-nm BaTiO3 nanocrystals,
which were functionalized as previously described (9, 10) and
conjugated to Cy5-coupled donkey anti-mouse IgG antibodies
(Jackson ImmunoResearch Laboratories, Inc.) based on cross-
linking reactions between amine groups on the BaTiO3 nanocrys-
tals and sulfhydryl groups on the IgG antibody (11). Unconju-
gated antibodies were removed by centrifugation and the final
solution was used after nanofiltering to remove clustered conju-
gates at a dilution of 1∶10. This step was followed by washes with
PBST. Cell boundaries were visualized by counterstaining the tis-
sue with fluorescent phalloidin-Alexa546 (Invitrogen Corp.).
Images were acquired using a Zeiss 510NLO microscope. For
three-channel confocal image acquisition, a femtosecond pulsed
laser tuned to 820 nm (for imaging SHG), a 543-nm He/Ne laser
line (for imaging phalloidin-Alexa546), and a 633 nmHe/Ne laser
line (for imaging Cy5) were used sequentially. Images were pro-
cessed using Adobe Photoshop CS3 (Adobe Systems).
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5. Kelsh RN, et al. (1996) Zebrafish pigmentation mutations and the processes of neural
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Mech Develop 120(11):1407–1420.
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70:1637–1643.
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for cytoplasmic crowding in living cells. Biophys J 87(5):3518–3524.
9. Hsieh CL, Grange R, Pu Y, Psaltis D (2009) Three-dimensional harmonic holographic
microcopy using nanoparticles as probes for cell imaging. Opt Express 17(4):
2880–2891.
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posites with high permittivity and dielectric strength. Adv Mater 19
(7):1001–1005.
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Pantazis et al. www.pnas.org/cgi/doi/10.1073/pnas.1004748107 2 of 7
Fig. S1. SHG signal properties of BaTiO3, ZnO, and SiC and multi-SHG imaging modality. (A) Displayed are the 3D normalized SHG signal data profiles of
barium titanate (BaTiO3), zinc oxide (ZnO), and silicon carbide (SiC) nanocrystals (signal ranging from 380 to 720 nm) generated by conventional two-photon
excitation (excitation ranging from 760 to 970 nm). Note that the SHG signal peaks are always half the wavelength of the incident excitation wavelength.
Regarding the higher frequency conversion efficiency at shorter wavelengths, this increase might be due to the fact that although the fundamental excitation
frequency is far off resonance for the materials tested in our wavelength dependence experiment, the resulting second harmonic frequency is indeed close to
resonance for all of the materials having band gap energies of around/less than 3 eV. Color code: dark blue corresponds to zero intensity and dark red cor-
responds to maximal intensity. (B and C) Multi-SHG imaging modality. (B) Displayed are the normalized SHG signal spectra of BaTiO3 (Upper) and SiC (Lower)
nanocrystals generated by tuning the excitation wavelength to 800 nm (solid line) and 880 nm (dashed line). (C) Single confocal sections showing comparable
SHG signal intensities of immobilized BaTiO3 and SiC nanocrystals in parallel. The noncentrosymmetric nanomaterials were sequentially excited with 800 nm
(Top) and 880 nm (Middle), respectively. Whereas the SHG signal of SiC nanocrystals is only readily detectable at 800 nm, the SHG signal of BaTiO3 nanocrystal is
visible at both excitation wavelengths. In a multi-SHG imaging modality, relative intensities are sufficient to be compared in order to distinguish different SHG
nanoprobe materials. Applying this information, one can now distinguish both nanomaterials (Bottom, false-colored picture: SiC nanocrystals in red, BaTiO3
nanocrystal in green). Bar corresponds to 500 nm.
Pantazis et al. www.pnas.org/cgi/doi/10.1073/pnas.1004748107 3 of 7
Normalized Intensity/Pixel 
Fr
eq
ue
nc
y
20
16
12
  8 
  4 
  0 
0          2            4            6            8           10 
50 nm 
- 50 nm 
- 0 nm 
- 25 nm 
A
CB
Dextran-Cascade Blue [mg/ml] 
0            0.25          0.5           0.75           1 
In
te
ns
ity
 [c
ou
nts
/pi
xe
l] 
300
250
200
150
100
  50 
    0
Fig. S2. Control experiments of BaTiO3 nanocrystal characterization. (A) AFM image of individual, well-isolated BaTiO3 nanocrystals. Displayed is an AFM
picture of single BaTiO3 nanoparticles immediately after ultrasonication and nanofiltering. The image shows that the nanoparticles have a diameter as well as a
height in the range of 25–35 nm. Color code: dark corresponds to zero height and bright corresponds to 50 nm height. (B) Flatfield image calibration. Average
corrected intensity over the whole spatial field of view versus different Dextran-Cascade blue concentrations. Three independent measurements for each
concentration are shown. A linear regression fit to the first five data points is represented by a red line. (C) The normalized intensity distribution of the
detected SHG diffraction-limited spots are shown in white columns. The red line represents the fitted sum of 2 Gaussians (black dash lines). The first peak
indicates a single SHG nanocrystals, the second to aggregates.
Pantazis et al. www.pnas.org/cgi/doi/10.1073/pnas.1004748107 4 of 7
5’ 
0’ 
10’ 
15’ 
Dextran-Alexa546 BaTiO3 Merge
20’ 
Dextran-Alexa546
BaTiO3
32 cell stage dome stage 
b
a
Fig. S3. SHG nanoprobes provide superior signal-to-noise ratio and do not bleach after in vivo injections. (A) Single-cell coinjections of BaTiO3 nanoparticles
and 10,000MWDextran-Alexa546 were performed at the 32-cell stage and imaged at the dome stage of zebrafish embryos. (B) Time-lapse images of individual
cells at the dome stage of a zebrafish embryo marked with BaTiO3 nanocrystals (Center column) and Dextran-Alexa546 (Left column). Right column is the
merged picture with white boxes magnified in the center and left columns. Times (0′, 5′, 10′, 15′, and 20′) indicate minutes at and after the start of the
experiment. Note that continuous scanning with intense excitation power levels bleaches quickly the organic dye, whereas the SHG signal of BaTiO3 stays
unchanged, allowing long-term nanoparticle tracking. Anterior to the left. Bar corresponds to 20 μm.
Pantazis et al. www.pnas.org/cgi/doi/10.1073/pnas.1004748107 5 of 7
BA
C D
>
1% 850nm 3% 850nm 
>
>
>
Fig. S4. SHG nanoprobes can be readily detected with increased imaging depth and provide superior signal-to-noise ratio when present in mammalian tail
tendon. (A and B) BaTiO3 nanocrystals were injected into one-cell stage colorless zebrafish embryos. Several days after cytoplasmic injection (around 72 hpf)
part of the zebrafish trunk was imaged with femtosecond pulsed 820-nm light. (A) Dorsal 3D reconstruction of the zebrafish trunk showing endogenous SHG
signal from trunk-muscles detected in transdirection (blue), SHG of BaTiO3 nanocrystals detected in epi- as well as in transdetection (white), and BODIPY TR
methyl ester dye labeling the extracellular matrix and cell membranes (red). Rostral front, caudal back. (B) Axial view of a slice of the trunk 3D reconstruction
(yellow box). Whereas endogenous SHG and the vital dye are only readily detectable in the first 100 μm, the cross-sectional view through the trunk muscle
shows that intense SHG signal of BaTiO3 nanocrystals is still detectable with increased imaging depth [here, nanocrystals (yellow arrow) present in the trunk of
a zebrafish at an imaging depth of around 200 μm]. Note that the power levels required to detect endogenous SHG are 10 times higher than those to visualize
BaTiO3. Bar corresponds to 50 μm. (C andD) BaTiO3 nanocrystals present inmouse tail slices of approximately 2–3-mm thickness. (C) One percent excitation with
femtosecond pulsed 850-nm light results in strong SHG signal from diffraction-limited BaTiO3 nanocrystals (two of three spots marked with arrowheads)
together with weak endogenous SHG signal originating from collagen in connective tissue of mouse tail tendon. (D) Increasing the excitation power level
to 3% results in robust endogenous SHG signal with regular and highly organized collagen fiber clearly observable. Note that the power levels required to
detect a strong signal from SHG nanocrystal signal spots is lower than for endogenous SHG of very highly aligned collagen fibers in mouse tail tendon. Bar
corresponds to 50 μm.
Movie S1. SHG nanoprobes neither bleach nor blink Time-lapse imaging of single BaTiO3 nanocrystal (Left) and CdSe/ZnS quantum dot (Right) immobilized in
20% polyacrylamide gel and illuminated with low intensity levels of 820-nm light 300 times with a scanning speed of 20 frames∕s.
Movie S1 (MOV)
Pantazis et al. www.pnas.org/cgi/doi/10.1073/pnas.1004748107 6 of 7
Movie S2. SHG nanoprobes do not saturate with increasing illumination intensity Image sequences of BaTiO3 nanocrystal (Left) and CdSe/ZnS quantum dot
(Right) immobilized in 20% polyacrylamide gel and rapidly illuminated with increasing 820-nm light intensity (1- to 40-fold).
Movie S2 (MOV)
Movie S3. SHG nanoprobes can be readily detected with increased imaging depth 3D reconstruction of imaging z sections of the zebrafish trunk showing
endogenous SHG signal from trunk muscles detected in transdirection (blue), SHG of BaTiO3 nanocrystals detected in epi- as well as in transdetection (white
and white), and BODIPY TR methyl ester dye labeling the extracellular matrix and cell membranes (red). In colorless mutant zebrafish embryos, light-scattering
iridophores are significantly reduced.
Movie S3 (MOV)
Pantazis et al. www.pnas.org/cgi/doi/10.1073/pnas.1004748107 7 of 7


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Second harmonic generating (SHG) nanoprobes for in vivo imaging

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