Gold Nanocluster-Mediated Cellular Death under Electromagnetic

Nov 8, 2017 - ARC Centre of Excellence in Convergent Bio-Nano Science and Technology, Centre for Advanced Imaging (CAI), The University of Queensland,...
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Gold nanocluster-mediated cellular death under electromagnetic radiation Anna Cifuentes-Rius, Angela Ivask, Shreya Das, Nuria Penya Auladell, Laura Fabregas, Nicholas L. Fletcher, Zachary H Houston, Kristofer James Thurecht, and Nicolas H. Voelcker ACS Appl. Mater. Interfaces, Just Accepted Manuscript • DOI: 10.1021/acsami.7b13100 • Publication Date (Web): 08 Nov 2017 Downloaded from http://pubs.acs.org on November 9, 2017

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Gold nanocluster-mediated cellular death under electromagnetic radiation

Journal: Manuscript ID Manuscript Type: Date Submitted by the Author: Complete List of Authors:

ACS Applied Materials & Interfaces am-2017-131004.R2 Article 01-Nov-2017 Cifuentes-Rius, Anna; Monash Institute of Pharmaceutical Sciences, Drug Discovery Disposition and Dynamics Theme Ivask, Angela; Keemilise ja Bioloogilise Fuusika Instituut Das, Shreya; University of South Australia - Mawson Lakes Campus Penya Auladell, Nuria; Monash Institute of Pharmaceutical Sciences; Institut Quimic de Sarria, Universitat Ramon Llull Fabregas, Laura; Monash Institute of Pharmaceutical Sciences; Institut Quimic de Sarria, Universitat Ramon Llull Fletcher, Nicholas; University of Queensland, Centre for Advanced Imaging Houston, Zachary; University of Queensland, Centre for Advanced Imaging Thurecht, Kristofer; The University of Queensland, Australian Institute for Bioengineering and Nanotechnology and Centre for Advanced Imaging Voelcker, Nicolas; University of South Australia - Mawson Institute,

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Gold nanocluster-mediated cellular death under electromagnetic radiation Anna Cifuentes-Rius ‡,§,#,†, Angela Ivask‡,§,∑, Shreya Das§, Nuria Penya-Auladell§,#,‡, Laura Fabregas#,‡, Nicholas L. Fletcher¥, Zachary H. Houston¥, Kristofer J. Thurecht¥, Nicolas H. Voelcker§,#,†,* §

ARC Centre of Excellence in Convergent Bio-Nano Science and Technology, Future

Industries Institute, University of South Australia, Mawson Lakes Campus, Mawson Lakes Boulevard, Mawson Lakes SA 5095, Australia #

Monash Institute of Pharmaceutical Sciences, Monash University, Parkville Campus, 381 Royal Parade, Parkville VIC 3052, Australia



Grup d’Enginyeria de Materials (GEMAT), Institut Quimic de Sarria, Universitat Ramon Llull, Via Augusta 390, Barcelona, 08022, Spain

¥

ARC Centre of Excellence in Convergent Bio-Nano Science and Technology, Centre for

Advanced Imaging (CAI), The University of Queensland, Building 57 Research Road, St Lucia QLD 4072, Australia KEYWORDS gold nanoclusters, microwave-frequency region, electromagnetic radiation, hyperthermia, cytotoxicity

Gold nanoclusters (Au NCs) have become a promising nanomaterial for cancer therapy due to their biocompatibility and fluorescent properties. In this study, the effect of ultrasmall 1 ACS Paragon Plus Environment

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protein-stabilized 2 nm Au NCs on six types of mammalian cells (fibroblasts, Blymphocytes, glioblastoma, neuroblastoma, and two types of prostate cancer cells) under electromagnetic radiation is investigated. Cellular association of Au NCs in vitro is concentration-dependent and Au NCs have low intrinsic toxicity. However, when Au NCincubated cells are exposed to 1 GHz electromagnetic field (microwave radiation), cell viability significantly decreases thus demonstrating that Au NCs exhibit specific microwave dependent cytotoxicity, likely resulting from localized heating. Upon i.v. injection in mice, Au NCs are still present at 24 h post administration. Considering the specific microwavedependent cytotoxicity and low intrinsic toxicity, our work suggests the potential of Au NCs as effective and safe nanomedicines for cancer therapy.

1. Introduction The possibility of using localized nanoparticle heating to remotely control biological functions has not gone unnoticed in the field of drug delivery and it has been explored for several biomedical applications, including cancer therapy and diagnostics as well as triggered drug/gene release and treatment of bacterial infections.1-5 The thermal dissipation of nanosize gold (Au NPs) under electromagnetic (EM) radiation allows noninvasive, triggered and localized therapies and can be induced by both infrared and radiofrequency/microwave radiation.6 Infrared light is commonly used for photothermal therapy, as infrared lasers and visible light can excite the surface plasmon resonance of Au NPs exploiting a wellunderstood mechanism.7 Electromagnetic (EM) irradiation between the radiofrequency (RF) and microwave regions for hyperthermia in cancer treatment has gained special attention in the last 10 years due to its ability to penetrate deeper within non-conducting materials.8-9 Yet the heating mechanism

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of Au NPs under RF and microwave irradiation is still not fully understood.6, 10 In a recent review by Ackerson et al., two independent research lines based on different operating frequencies, RF or microwave, are categorized. The review revealed that most papers reporting Au NP heating use a RF generator called “Kanzius Machine” (Therm-Med LLC, Erie, PA), which operates at 13.56 MHz and at relatively high power output (up to 1000 W).6 Teams of chemists, radio-engineers and academic surgeons have investigated the use of this machine and Au NPs between 5 to 100 nm in diameter to kill cancer cells.8, 11 They proved that Au NPs can convert electromagnetic energy into heat under 13.56 MHz EM field and the efficacy of heating depends on concentration and diameter of the Au NPs.9, 11 The localized heat released from Au NPs under RF denatures proteins, disrupts lipid bilayers, and results in irreparable damage to intracellular structures and organelles of cancer cells.9 Other authors have used microwave frequency EM radiation to induce the heating of Au NPs. HamadSchifferli et al. found that hairpin-loop DNA covalently attached to 1.4 nm diameter gold nanocrystals was able to dehybridize into solution when exposed at 1 GHz EM field (microwave range) due to the localized heat generated.12 On the other hand, the heat release by Au NPs in the microwave range has been shown to be very localised as recently proven by Kabb et al. In this work, they demonstrated, using a “polymeric thermometer”, that the heat generated by 5 nm Au NPs under microwave is localized within a radial distance from the nanoparticle surface less than 2 nm and is quickly dissipated at longer distances.13 This study by Kabb et al. was the first one to directly prove the surface-specific heating from the nanoparticles, rather than the increase of temperature from the bulk solution. We have also recently indirectly demonstrated remote heating of thermoresponsive nanomaterials by microwave.14 The efficacy of microwave EM field in heating tissues is also already clinically proven. It has been shown that microwave frequencies (typically 915 MHz or 2.45 GHz) can heat tissues to cytotoxic level using an applicator antenna.15-16 It must be however noted that

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these studies with applicator antenna have been conducted without any addition of nanoparticles and thus, the localization of heat has been controlled only by positioning the antenna. Addition of specifically localized nanoparticles to such a system would increase the precision of heating and instead of an invasive antenna would allow to use externally created microwave EM field. To our knowledge, microwave-induced heating of Au NPs for clinical cancer hyperthermia has not been explored.4, 6 Among Au NPs, gold nanoclusters (Au NCs) have attracted great attention in the scientific community as they are atomically monodispersed sub-nanometer particles (< 2 nm in diameter) with significantly different characteristics than their bigger counterparts in terms of stability, and electronic and optical properties.6,

17

For example, Au NCs do not show

plasmon surface resonance phenomenon typically seen in larger Au NPs.17-18 Instead, they exhibit near infrared fluorescence due to their molecular-like electronic properties. With other advantages such as large Stokes shift, good dispersibility in water, and chemical stability, they hold great promise for biomedical applications like sensing, bioimaging and cancer therapy.17,

19-24

Some studies have found that Au NCs have also longer blood

circulation times and increased tumor penetration rates than their larger counterparts.25 Moreover, akin to biomineralization processes, stable Au NCs can be synthesized by using biomolecules like bovine serum albumin (BSA) as templates.26 Another fascinating property of Au NCs is that they can behave as a superatom paramagnet when they are chemically oxidized.27-28 This is particularly interesting because paramagnetic Au NCs were shown to respond to an oscillating magnetic field component of the EM radiation generated by a solenoid similarly to magnetic iron oxide nanoparticles and therefore generate heat.27 We have recently proved that Au NCs can be used for hyperthermia in combination with chemotherapy in B-lymphocytes when exposed to a microwave field.29

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In this study, we investigated the cytotoxic effects of BSA-capped Au NCs in different types of cells before and after being exposed to microwave field. As far as we know, this is the first work studying the hyperthermia-mediated cytotoxicity using Au NCs and microwaves in different cell lines. Thus, the heating of Au NC under a 1 GHz EM field (microwave range) and a solenoid as applicator antennae – therefore favoring the magnetic field6 – has been used as a cancer therapy for the first time. Our results showed that Au NCs are promising means for microwave-induced hyperthermia and cell killing in vitro. Further studies are required to show the applicability of Au NCs in vivo.

2. Experimental section 2.1. Preparation and characterization of Au NCs. Au NCs were synthesized following to the protocol described by Xie et al.26 Typically, 5 mL of 10 mM aqueous solution of HAuCl4 (Sigma-Aldrich) was added to a 50 mg/mL (5 mL, 40oC) BSA (Sigma-Aldrich) solution. The mixture was allowed to stir for 2 min, after which 0.5 mL of 1 M NaOH (Sigma) was added. The reaction was left overnight at 40oC and protected from light. The as synthesized Au NCs were dialyzed (cut-off 10 kDa) against MilliQ water for 12 h in order to remove unbound fragments of BSA and salts. Au NCs were characterized by transmission electron microscopy (TEM, JEOL JEM2100F). Samples were diluted in ethanol and deposited on Formvar film coated cooper grids (PST ProSciTech). Images were acquired at an accelerating voltage of 200 kV. Photographs of the Au NCs solution synthesized at different concentrations together with the controls were taken with and without illumination with an ultraviolet lamp (excitation wavelength 365 nm). Fluorescence spectra were acquired with a Cary Eclipse fluorescence spectrometer (Agilent Technologies) exciting the solution at 460 nm. Dynamic light scattering (DLS) measurements were performed with a Malvern Zetasizer nano ZS following a recently

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established protocol.30 Sodium chloride (Sigma, NaCl) solutions were prepared in MilliQ water (0.04-5 M) and mixed 1:1 (v/v) with Au NC solution (in MilliQ water). DLS measurements were done immediately after mixing the two solutions (day 1). The same solutions were stored at room temperature, at 4oC and 37oC, and measured again at day 5 and day 12. All measurements were done in triplicates. Size distribution of a solution of Au NCs (0.1 mg/mL) was also measured. Moreover, the zeta (ζ) potential of the purified Au NCs diluted 9:1 with a solution of 10 mM NaNO3 was recorded. 2.2. Cell culture. Cultures of HR1K (American Type Culture Collection, ATCC, acute Bcell leukemia, suspension cell line), U-87 (human glioblastoma cell line, ATCC HTB-14) SHSY5Y (human bone marrow neuroblastoma cell line, ATCC CRL-2266), NIH/3T3 (mouse fibroblast cell line, ATCC CRL-1658), PC3 (human prostate carcinoma cell line, ATTC CRL-1435) and C4-2B (Metastatic subline derived from LNCaP, human prostate carcinoma cell line, kindly provided by the Prostate Cancer Research Group at the South Australian Health and Medical Research Institute) cells were used. HR1K cells were cultured in RPMI 1640 medium (4.5 g glucose/L) supplemented with 10% FBS, 2 mM Glutamax (Life Sciences), 1 mM Na-pyruvate, 100 U penicillin and 100 µg/mL streptomycin; U87 and SHSY5Y cells were cultured in DMEM medium supplemented with 10% FBS, 2 mM Glutamax and 100 U penicillin and 100 µg/mL streptomycin. Cells were routinely cultivated either on non-cell culture treated Petri dishes (HR1K) or in cell culture treated culture flasks (adherent cell lines). Cells were cultured at 37 °C and 5% CO2, and cell density was kept between 2×105-2×106 for HR1K and 5×104-5×105 for U87, SHSY5Y, and PC3. Cell culture medium was changed and/or cells were subcultured every 2-3 d. 2.3. Cell exposure to Au NCs in vitro. HR1K cells were harvested by centrifugation, cell density was adjusted to 2×105 and 0.5 mL cells were seeded to 48-well micoplates. U87, SHSY5Y, PC3, C4-2B and 3T3 cells were trypsinized, centrifuged (150 g, 5 min) and

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resuspended in cell culture medium to a cell density of 4×104 cells/mL. 1mL of cell suspensions was seeded to polylysine (for coating 0.1% polylysine in sterile DI water was exposed to glass for 30 min) and sterilized 50 mm2 (10 mm × 5 mm) glass coverslips that were placed in 12-well microplates. To perform confocal microscopy imaging, 2.5 mL of cell suspensions was seeded to 1.8 x 1.8 cm 0.17 µm thickness coverslips on 6-well plates. HR1K cells on 48-well microplates and adherent cells on 12- or 6-well plates were grown for 24 h and Au NCs (1-100 µg/mL) were added into the cell culture medium. The cells with Au NCs were grown for another 24 h to allow for cellular binding and uptake after which the cells were washed with fresh cell culture medium. For washing, the adherent cells were simply rinsed with cell culture medium but HR1K cells were washed using three resuspension-centrifugation (150 g, 5 min) cycles. An equal volume of cell culture medium was added and the cells were subjected either to microwave radiation, imaging or ICP-MS analysis. 2.4. Analysis and visualization of cell-associated Au in vitro. Cell-associated Au was analyzed qualitatively using fluorescence microscopy and flow cytometry, and quantitatively using ICP-MS. Exposure to 1-100 µg/mL Au NCs was performed as described above. For fluorescence microscopy, the cells were fixed for 10 min in 4% formaldehyde and stained with phalloidin-TRITC (10 µg/mL) and Hoechst 33342 (0.12 µg/mL) for 30 min. Glass coverslips with adherent cells were placed immediately to microscopy slides; suspension cells were pipetted onto microscope slides and covered with 0.17 µm thickness coverslips. The cells were imaged using structured illumination mode in Zeiss Elyra confocal microscope and 405 nm, 488 nm and 561 nm lasers. Emission of stained nuclei, cellular cytoskeleton and Au NCs were measured at 420-480 nm, 570-620 nm and ˃655 nm, respectively. For flow cytometry, adherent cells were trypsinized and suspension cells were

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used directly. The cells were analyzed using an Amnis Image Stream X imaging flow cytometer in bright field and fluorescence at 488 nm excitation/660-745 nm emission. For ICP-MS, the cells were digested with aqua regia (3:1 conc. HCl:HNO3) (900 µL of aqua regia was added to 100 µL of cells) overnight. Alternatively, Au NC exposed HR1K cells were chemically etched prior the digestion to remove cell surface bound nanoparticles. Cells were treated with 0.034 mM/0.2 mM I2/KI mixture for 1 min, washed, and digested as above. Digested samples were then diluted in a diluent containing 2.4% HCl, 0.04% HNO3 and 0.5% thiourea, and Au content was analyzed with a qqq-ICP-MS (Agilent 8800). Mass of Au per cell was calculated per cell; for that, the number of cells were counted before EM exposure. Adherent cells that were trypsinized from glass surface and suspension cells were counted using hemocytometer or flow cytometer. 2.5. Biodistribution of Au NCs in vivo. All studies were in accordance with the guidelines of the Animal Ethics Committee of The University of Queensland (UQ; Approval AIBN/CAI/530/15/ARC/NHMRC), and Australian Code for the Care and Use of Animals for Scientific Purposes. Healthy male BALB/c nude mice (~20 g; Animal Resources Centre, Australia) from 8 weeks old were imported into the CAI animal holding facility and monitored for 1 week prior to the study in order to acclimatize to the environment. All animals were provided with free access to food and water before and during the imaging experiments. Mice were anaesthetized using 2% isoflurane (gradually reduced as required to maintain anesthesia and respiratory rate) in oxygen at a flow rate of 2 L/min and Au NCs (0.8 mg/mL) were administered via tail vein i.v. injection (29G) in 200 µL phosphate buffered saline. Mice were then anaesthetized (as above) and fluorescence images acquired at 0.5, 2, 4, 6 and 24 h post injection using an In Vivo MS FX Pro instrument (now supplied by Bruker Corporation) with mice in both prone and supine orientations. Au NC fluorescence images were collected

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with 480 ± 10 excitation filters, respectively using a 700 nm ± 17.5 nm emission filter set (fstop 2.80, 4 × 4 pixel binning, 190 mm field of view and 5 sec exposure time). X-ray images (f-stop 2.80, 0.2 mm aluminum filter, 190 mm FOV, 10 s acquisition time) were acquired to provide anatomical registration. All images were processed using Image-J software (National Institutes of Health). Fluorescence images were false colored and overlaid onto X-ray images. 2.6. Ex vivo imaging of the main organs. At 24 h post injection, blood samples were collected via heart puncture (29G) before the mice were sacrificed via cervical dislocation. Major organs (heart, lungs, spleen, liver, kidneys and gastrointestinal tract) and blood were imaged ex vivo using the same acquisition settings as above. Semi-quantitative region of interest (ROI) analysis of ex vivo fluorescence images was conducted utilizing Bruker MI SE software to obtain values of sum fluorescence intensity per organ. 2.7. Quantification of Au content accumulated in each organ. The heart, lungs, spleen, liver and kidneys of each mouse was weighted and mechanically homogenized through a 70 µm cell strainer using cold 2% (w/v) bovine serum albumin and 1% (w/v) sodium azide in phosphate buffered saline (PBA) to suspend the cells. Organ cell suspensions and blood samples were centrifuged (500 × g for 5 min and 200 × g for 10 min, respectively), the supernatant removed and the remaining cell pellets resuspended in cold 50:50 4% (w/v) paraformaldehyde/PBA and incubated in the dark at 4 °C overnight. Fixed cell suspensions were then centrifuged (500 × g for 5 min), the supernatant removed and each pellet resuspended in cold 1 mL PBA. Cell suspensions were then digested in aqua regia as described before until full digestion of the organ cell suspensions was achieved. Au content in digested samples was analyzed by ICP-MS following the same protocol previously described. The amount of Au per organ (in mass) per each replicate and its average were calculated and plotted.

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2.8. Exposure of cells to microwave irradiation in vitro. Prior to microwave irradiation, HR1K suspension cells and 3T3, U87, SHSY5Y, PC3 and C4-2B adherent cells were exposed to Au NCs as described above. A control without Au NCs was included for all cell lines (n = 3). Cells without Au NCs (n = 3) were also exposed to microwave in order to study the effect of the electromagnetism on cells without Au NCs. For microwave exposure, adherent cells on coverslips were added to sterile microcentrifuge tubes into which 500 µL of cell culture media was added (so that the glass slide was soaked in the cell medium). In case of suspension cells, 500 µL of cells were pippeted to microcentrifuge tubes. Microcentrifuge tubes with cells were then exposed to 1 GHz (microwave range) electromagnetic radiation for 8 min for all cell lines except C4-2B prostate cancer cell line that was exposed to the microwave field for 7 min (optimization experiments were carried out within a 3-15 min range) using a custom-made EM generator described elsewhere (see Supporting Information, Figure S6).14 Between the successive irradiations, a 2 min interval was applied to cool down the system. During the microwave irradiation process, the cells were allowed to stay in the closed microcentrifuge tubes not more than 60 min (no significant cell death was observed when either adherent or suspension cells were kept outside the temperature and CO2 controlled environment for 60 min; data now shown). 2.9. Assessment of cellular viability after microwave irradiation. After microwave irradiation the cells were placed back to microplate and 37°C, 5% CO2. The B-lymphocyte suspension cells were pipetted to 48-well microplates and glass slides with adherent cells were placed onto a 24-well plate. In case of adherent cells, cell culture medium that was used in microcentrifuge tubes at the time of microwave irradiation was placed over the slides with cells. The cells were incubated at 37°C and 5% CO2 for 24 h. Viability of adherent cells was assessed by resazurin assay (resazurin reagent was added to cell culture medium at 30 µg/mL, cells were incubated for 4 h and fluorescence at 530 nm excitation / 590 nm emission was

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measured). The viability of suspension cells was assessed by staining the cells with fluorescein diacetate (FDA, final concentration 0.5 µg/mL) and propidium iodide (PI, final concentration 5 µg/mL) (cell staining was performed in PBS for 15 min at room temperature) and analyzing the cells with an imaging flow cytometer (Amnis Image Stream X). At least 10,000 events were collected, populations of live cells (stained with FDA, 488/525 nm) and dead cells (stained with PI, 488/590 nm) were selected and the percentage or each cell population was calculated. In parallel to microwave irradiated cells, the viability of nonirradiated cells was also analyzed using analogous methods. 2.10. Detection of apoptosis in microwave-irradiated cells. Annexin V-FITC Apoptosis Detection Kit (Sigma) was used as suggested by manufacturer. HR1K suspension cells that had been exposed to 1-100 µg/mL AuNCs for 24 h and subsequently treated with microwave (or not treated) were incubated in Annexin V binding buffer (Sigma) with Annexin V FITC Conjugate (100 x dilution from Sigma kit) and propidium iodide (50x dilution from Sigma kit) for 10 min. The cells were analyzed using an Amnis imaging flow cytometer where apoptotic cells were identified using 488 nm excitation/480-560 nm emission and late apoptotic plus necrotic cells using 488 nm excitation/595-660 nm emission.

3. Results and Discussion 3.1. Synthesis and characterization of fluorescent Au NCs We synthesized Au NCs templated by BSA given its biocompatibility, stealth properties and the possibility to carry out further functionalization with targeting moieties.26,

31

The

synthesized Au NCs are stabilized by BSA molecules as reported by Xie et al.,26 showed an intense red fluorescence emission under UV light and an emission peak at around 660 nm when excited at 488 nm (Figure 1 A and B). As expected, no surface plasmon resonance was observed at this particle size (Figure 1 B). TEM showed that the formed Au NCs were 1.7 ±

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0.4 nm in core diameter with a narrow size distribution (Figure 1 C). The hydrodynamic diameter (dH) of Au NC was also measured by dynamic light scattering (DLS) and their colloidal stability in front of salt concentration and time was investigated (Figure 1 D). Colloidal stability in physiological conditions is paramount to avoid agglomeration of nanoparticles, which can have a direct impact on cellular internalization complicating dosimetry.32 In particular, salt (NaCl), which is present at high concertation in the cell culture media, is one of the main reasons why particles agglomerate.30 Because Au NCs were suspended in osmotically and pH controlled buffer (PBS 1x pH 7.4) before in vitro and in vivo studies, the effect of salt concentration present in the media was explored. Since we know that an increase of dH it is likely due to nanoparticle aggregation, we studied the effect salt-induced aggregation of Au NCs using DLS. Therefore, the colloidal stability of Au NCs under physiological conditions can be proved.30 The DLS measurement was carried out immediately after adding the NaCl solution to the Au NC solution (in MilliQ water), and again 5 and 12 days later, since aggregation can be a time-dependent process. The dH was initially 8.8 ± 0.5 nm in the presence of NaCl 0.02 M which remained constant at higher salt concentrations (2.5 M) with a dH of 11.6 ± 0.5 nm (Figure 1 D). The measurement remained the same when repeated at day 5 and 12, showing the colloidal stability of the BSA-coated Au NCs. The colloidal stability was also confirmed after measuring the zeta (ζ) potential, which resulted in 33-35 mV. Additionally, their stability in physiological conditions was also confirmed at 4oC and 37oC by performing the same experiment at these temperatures (see Supporting Information, Figure S1).

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Figure 1. Characteristics of Au nanoclusters (Au NCs). A: appearance under visible (top images) and UV light (bottom images); Au NC concentration was 700 µg/mL, and water and BSA solution were used for comparison; B: absorbance and fluorescence (after excitation at 488 nm) spectra of 100 µg/mL Au NCs; C: TEM view of Au NCs (scale bar 20 nm); insert shows magnified view of the NCs (scale bar 1 nm). D: Salt-induced aggregation of Au NCs over time measured by DLS. DLS measurement of Au NCs in PBS at room temperature gave a dH of 9.1 nm (Pdl of 0.264), similarly to what was observed in the salt-aggregation study. Interestingly, the dH of Au NCs matches to the one observed for BSA alone.33 This observation matches with the studies that observed how BSA acts as a template for the formation and stabilization of Au NCs without significantly affecting its secondary structure.34-36 The BSA:Au ratio is a key to achieve subnanometer-sized clusters because BSA acts as a template and the formation of Au NC is only possible when (a) enough BSA is in the solution and (b) the pH is raised above 10.17 During formation of Au NCs, first BSA coordinates Au3+ ions through the histidine groups within its structure and after rising the pH, the tyrosine residues are able to reduce the Au3+ ions in a controlled way while the cysteine amino acids

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stabilize the formed cluster via disulphide groups. We confirmed the importance of the BSA concentration and the pH of the reaction by exploring the synthesis at different conditions (Figure S2 in the Supporting Information). We observed that, with the same amount of Au3+ (10 mM), the minimum concentration of BSA in which the Au NCs were successfully formed was 50 mg/mL (Figure S2a), which was used throughout the study for the synthesis of Au NCs. We also proved that pH of the reaction less than 11 did not result in formation of high quality Au NCs. At pH less than 8, no Au NCs were produced whereas at pH 8, heterogeneous Au NCs with relatively low fluorescence intensity were formed (Figure S2b).

3.2. Association of Au NCs in vitro with different cell types Due to the ability of Au NPs to induce hyperthermia only in very close vicinity – some nanometers from the particles surface,13 cellular localization of those particles is crucial when their cytotoxicity under EM is studied. To qualitatively and quantitatively assess the amount of cell-associated Au NCs – either cell surface bound or internalized Au NCs, we used fluorescence imaging and inductively-coupled plasma mass spectrometry (ICP-MS) (Figure 2).

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Figure 2. Cellular association of Au NCs during 24 h exposure. Fluorescence microscopy images of non-exposed and Au NC exposed HR1K (A1-A3), U87 (B1-B3), SHSY5Y (C1C3), 3T3 (D1-D3), PC3 (E1-E3) ja C4-2B (F1-F3) cells (scale bar: 10 µm). In non-exposed cells (column 1; A1-F1) and Au NC exposed cells (column 2; A2-F2), nuclei are stained blue with Hoechst 33342, cytoskeleton yellow and Au NCs show red. Column 3 (A3-F3) is identical with column 2, but shows only nuclei and Au NCs. White arrows indicate red fluorescence originating from Au NCs. Quantification of cell-associated Au with ICP-MS in HR1K (A4), U87 (B4), SHSY5Y (C4), 3T3 (D4), PC3 (D4) and C4-2B (F4) cells at different Au NC exposure concentrations (n = 3).

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Cellular association of Au NCs was studied using mouse fibroblasts (3T3) and five cancerous cell lines from human: B-lymphocytes from lymphoma (HR1K), U87 from glioblastoma, SHSY5Y from neuroblastoma, PC3 and C4-2B from prostate. Using fluorescence microscopy, we tracked Au NCs’ intrinsic fluorescence (488 nm excitation/~650 nm emission) associated with cells. In Au NC-exposed cells, red fluorescing areas corresponding to Au NCs were visible in and around the cells (Figure 2 A2, B2, C2, D2, E2 and F2; these areas are also emphasized with white arrows on Figure 2 A3, B3, C3, D3, E3 and F3). ICPMS results show that, in general, the cell-associated mass of Au was 170-225 fg per each cell that was exposed for 24 h to 100 µg Au NCs/mL, and 100-230 fg for those exposed to 50 µg Au NCs/mL. Below 50 µg Au NCs/mL exposure concentration the cell-associated mass of Au decreased linearly (Figure 2 A4, B4, C4, E4 and F4). Although the amount of Au NCs associated with each cell correlated well with Au NC exposure concentration, our data indicate that in general, Au NCs associated with cells at a relatively low efficiency – only 0.1-0.3% of the total mass of Au to which the cells were exposed during 24 h was found in association with cells in ICP-MS analysis. This may be due the high colloidal stability of Au NCs at 37oC as demonstrated before (Figure S1b). Because Au NCs did not sediment at the bottom of the well where the cells were seeded, the Au NCs-cell interaction was diminished and therefore, low amount of Au NCs were able to be internalized by the cells.32 On the other hand, even the percentage of cell-associated Au NCs appeared relatively low, 170-225 fg Au per cell corresponds to 20-30×106 Au NCs. In order to decipher the nature of cellular association with Au NCs, i.e., if the clusters were intracellular or externally bound, we applied to Au NC-exposed HR1K cells a chemical etching procedure that according to Cho et al.37 causes removal of extracellularly bound Au particles. The results show concentration-dependent increase in cellular uptake of Au NCs up to 6 µg Au NCs/mL after which the intracellular concentration of Au NCs remained constant

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and the percentage of cell-surface-bound Au NCs increased (Figure S3). For example, from cells that were pre-exposed to 100 µg/mL of Au NCs, approximately 66% of Au initially associated with the cells was removed by chemical etching. In general, in HRIK cells 90-34% of the Au NCs, depending on the exposure concentrations, was internalized by the cells while the rest remained bound on cell surface.

3.3. In vivo biodistribution of Au NCs Elucidation of the in vivo biodistribution of nanomaterials is a key preliminary study to understand their potency under physiological conditions and bioavailability. Since Au NCs exhibit NIR fluorescence, their in vivo biodistribution can be conveniently tracked by fluorescence imaging. In this study, we performed both in vivo and ex vivo fluorescence imaging of intravenously (i.v.) administered Au NCs to mice (8 µg/g), to semi-quantitatively assess their biodistribution and bioavailability. Real-time mouse images were taken at different time-points after injection, similarly to other biodistribution studies done for Au NCs and other nanomaterials.31, 38 We observed that Au NCs were still present in the mouse 24 h post i.v. administration (Figure 3 A) since there is fluorescence signal observed, suggesting good bioavailability.

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Figure 3. Distribution of Au NCs in mice. Au NCs were administered i.v. through the tail vein. A: In vivo fluorescence imaging of mice in supine (top panels) and prone (lower panels) position are shown; false color scale is indicative of Au NC concentration. B: ICP-MS analysis of the organs of Au NC-injected mouse, performed after homogenization of the separated organs. Because Au NCs did not show specific organ accumulation in vivo, ex vivo imaging was used to further probe biodistribution. We collected liver, kidneys, spleen, lungs, heart, the gastrointestinal tract and a drop of blood and analyzed their fluorescence ex vivo (Figure S4a). In Au NC-exposed mice, higher fluorescence intensity was observed in the liver compared to the control. High fluorescence detected in the gastrointestinal tract of Au NC-injected mice was also present in control mice and therefore, can be attributed to autofluorescence. Semiquantitative region of interest (ROI) analysis of the fluorescence signal of each organ of the three injected mice was performed (Figure S4b). For the other organs, the fluorescence levels in the Au NC-injected mice were similar to the organs harvested from control mice (slight but 18 ACS Paragon Plus Environment

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not statistically significant increase in fluorescence was observed in liver of Au NC-exposed mice). In order to quantify the amount of Au accumulated in each organ, the organs were homogenized and digested in aqua regia for ICP-MS analysis (Figure 3 B). The results showed that Au NCs accumulated preferably in liver where the concentration of Au reached 12,164 ± 1,158 ng/g. Au was detected also in kidneys and spleen which accumulated around 3,000 ng Au/g. We suggest that Au NC fluorescence in those organs could not be seen ex vivo (Figure S4b) due to low limit of detection of the methodology. Accumulation of Au NCs in liver and spleen may be due to the uptake of clusters through macrophages residing in the mononuclear phagocyte system (MPS) as has been observed for others nanomaterials.39

3.4. In vitro cytotoxicity of Au NCs under microwave irradiation The final goal of this study was to assess the ability of Au NCs to induce cellular hyperthermia and cellular death under microwave irradiation. Before that, we measured the increase in bulk solution temperature relative to a control without Au NCs when exposed to microwave. Despite concentrating the Au NC solution to 2 mg/mL, the temperature of the control was only ~2oC below the measured for the Au NC solution. Kabb et al. directly measured the temperature of the nano-environment of microwave-induced heating of Au NP using a “polymeric thermometer”.13 This work found that the local temperature around the Au NP increased up to 70°C, while the temperature of the bulk solution temperature only reached 40°C. However, the temperature differential decreased drastically at a greater distance than 2 nm away from the particle surface. These results match our observations, suggesting that the heating happens locally within the Au NCs surface and then it is quickly dissipated to the bulk solution. We hypothesized then that Au NCs would specifically induce localized cytotoxicity in EM fields while being harmless otherwise, and hence first evaluated the cellular effects of those

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particles in the absence of EM radiation. As expected,40-41 the viability of cells that had been exposed to varying concentrations of Au NCs (up to 100 µg/mL) was high (around 90%) (Figure 4 A). To assess the cytotoxicity of Au NCs under microwave field, we first ensured that the EM radiation alone did not affect the cellular viability. In general, increasing microwave radiation times resulted in increased cellular death (Figure S5). For example, 10 min exposure to 15 W microwave radiation resulted in death of 50% HR1K B-lymphocytes and in death of 32 % U87 glioblastoma cells. We suggest that this unspecific cell death was due to the rise in temperature of the copper coil in the EM setup (described in Figure S6) which underwent heat exchange with the cell culture medium. Our optimization study (Figure S5a, b, c) showed that the largest difference between cell viability in non-exposed and Au NC-exposed cells under microwave radiation was achieved when the microwave radiation lasted for 8 min; this radiation time was selected for all further experiments except for C4-2B prostate cancer cell line which remained unaffected by the microwave radiation at a maximum time of 7 min (Figure S5d). Therefore, at the chosen microwave exposure times, and despite the unspecific heating of the cell culture media due to the heating of the coil, there was not significant cell death observed in cells without Au NCs.

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Figure 4. Cellular effects of Au NCs. A: viability of cells of HR1K B-lymphocytes, U87 glioblastoma cells, 3T3 fibroblasts, SHSY5Y neuroblastoma cells, PC3 and C4-2B prostate cancer cells, exposed to different concentrations of Au NCs for 24 h, no microwave treatment. B: viability of the same cells after being treated with microwave for 8 min or 7 min for the C4-2B cells. * indicate conditions at which cellular viability was different (p