In vitro and in vivo mapping of drug release after laser ablation thermal therapy with doxorubicin-loaded hollow gold nanoshells using fluorescence and photoacoustic imaging.

Doxorubicin-loaded hollow gold nanoshells (Dox@PEG-HAuNS) increase the efficacy of photothermal ablation (PTA) not only by mediating efficient PTA but also through chemotherapy, and therefore have potential utility for local anticancer therapy. However, in vivo real-time monitoring of Dox release and temperature achieved during the laser ablation technique has not been previously demonstrated before. In this study, we used fluorescence optical imaging to map the release of Dox from Dox@PEG-HAuNS and photoacoustic imaging to monitor the tumor temperature achieved during near-infrared laser-induced photothermal heating in vitro and in vivo. In vitro, treatment with a 3-W laser was sufficient to initiate the release of Dox from Dox@PEG-HAuNS (1:3:1 wt/wt, 1.32 × 10(12)particles/mL). Laser powers of 3 and 6W achieved ablative temperatures of more than 50°C. In 4T1 tumor-bearing nude mice that received intratumoral or intravenous injections of Dox@PEG-HAuNS, fluorescence optical imaging (emission wavelength = 600 nm, excitation wavelength = 500 nm) revealed that the fluorescence intensity in surface laser-treated tumors 24h after treatment was significantly higher than that in untreated tumors (p = 0.015 for intratumoral, p = 0.008 for intravenous). Similar results were obtained using an interstitial laser to irradiate tumors following the intravenous injection of Dox@PEG-HAuNS (p = 0.002 at t = 24h). Photoacoustic imaging (acquisition wavelength = 800 nm) revealed that laser treatment caused a substantial increase in tumor temperature, from 37 °C to ablative temperatures of more than 50 °C. Ex vivo analysis revealed that the fluorescence intensity of laser-treated tumors was twice as high as that of untreated tumors (p = 0.009). Histological analysis confirmed that intratumoral injection of Dox@PEG-HAuNS and laser treatment caused significantly more tumor necrosis compared to tumors that were not treated with laser (p<0.001). On the basis of these findings, we conclude that fluorescence optical imaging and photoacoustic imaging are promising approaches to assessing Dox release and monitoring temperature, respectively, after Dox@PEG-HAuNS-mediated thermal ablation therapy.

[1]  M. Gulsoy,et al.  Tm:Fiber laser ablation with real‐time temperature monitoring for minimizing collateral thermal damage: ex vivo dosimetry for ovine brain , 2013, Lasers in surgery and medicine.

[2]  Wei Lu,et al.  Targeted Photothermal Ablation of Murine Melanomas with Melanocyte-Stimulating Hormone Analog–Conjugated Hollow Gold Nanospheres , 2009, Clinical Cancer Research.

[3]  Wei Lu,et al.  In vitro and in vivo targeting of hollow gold nanoshells directed at epidermal growth factor receptor for photothermal ablation therapy , 2008, Molecular Cancer Therapeutics.

[4]  Dong Liang,et al.  A chelator-free multifunctional [64Cu]CuS nanoparticle platform for simultaneous micro-PET/CT imaging and photothermal ablation therapy. , 2010, Journal of the American Chemical Society.

[5]  R. Stafford,et al.  Nanoshell-mediated near-infrared thermal therapy of tumors under magnetic resonance guidance , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[6]  Chun Li,et al.  Exceptionally high payload of doxorubicin in hollow gold nanospheres for near-infrared light-triggered drug release. , 2010, ACS nano.

[7]  M. Grinstaff,et al.  Therapeutic and diagnostic applications of dendrimers for cancer treatment. , 2008, Advanced drug delivery reviews.

[8]  Kai Yang,et al.  Graphene in mice: ultrahigh in vivo tumor uptake and efficient photothermal therapy. , 2010, Nano letters.

[9]  Mauro Ferrari,et al.  Intravascular Delivery of Particulate Systems: Does Geometry Really Matter? , 2008, Pharmaceutical Research.

[10]  S. Emelianov,et al.  Tissue-mimicking phantoms for photoacoustic and ultrasonic imaging , 2011, Biomedical optics express.

[11]  S. Emelianov,et al.  Photoacoustic imaging and temperature measurement for photothermal cancer therapy. , 2008, Journal of biomedical optics.

[12]  R. Stafford,et al.  Theranostics With Multifunctional Magnetic Gold Nanoshells: Photothermal Therapy and T2* Magnetic Resonance Imaging , 2011, Investigative radiology.

[13]  Xiaohua Huang,et al.  Cancer cell imaging and photothermal therapy in the near-infrared region by using gold nanorods. , 2006, Journal of the American Chemical Society.

[14]  Stanislav Emelianov,et al.  Sensitivity enhanced nanothermal sensors for photoacoustic temperature mapping , 2013, Journal of biophotonics.

[15]  Leon Hirsch,et al.  Nanoshell-Enabled Photonics-Based Imaging and Therapy of Cancer , 2004, Technology in cancer research & treatment.

[16]  Lihong V. Wang,et al.  Thermoacoustic and photoacoustic sensing of temperature. , 2009, Journal of biomedical optics.

[17]  D. P. O'Neal,et al.  Photo-thermal tumor ablation in mice using near infrared-absorbing nanoparticles. , 2004, Cancer letters.

[18]  Jung Ho Yu,et al.  Designed Fabrication of a Multifunctional Polymer Nanomedical Platform for Simultaneous Cancer‐ Targeted Imaging and Magnetically Guided Drug Delivery , 2008 .

[19]  F. Maxfield,et al.  Endocytic recycling , 2004, Nature Reviews Molecular Cell Biology.

[20]  Pai-Chi Li,et al.  Photoacoustic/ultrasound dual-modality contrast agent and its application to thermotherapy. , 2012, Journal of biomedical optics.

[21]  W. Dewey,et al.  Thermal dose determination in cancer therapy. , 1984, International journal of radiation oncology, biology, physics.

[22]  R. Weissleder A clearer vision for in vivo imaging , 2001, Nature Biotechnology.

[23]  J. Lepock,et al.  Cellular effects of hyperthermia: relevance to the minimum dose for thermal damage , 2003, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[24]  Wei Lu,et al.  Drug Delivery: Hollow Copper Sulfide Nanoparticle‐Mediated Transdermal Drug Delivery (Small 20/2012) , 2012 .

[25]  Chun Xing Li,et al.  Photothermal-chemotherapy with doxorubicin-loaded hollow gold nanospheres: A platform for near-infrared light-trigged drug release. , 2012, Journal of controlled release : official journal of the Controlled Release Society.

[26]  R. Stafford,et al.  Near-infrared light modulated photothermal effect increases vascular perfusion and enhances polymeric drug delivery. , 2011, Journal of controlled release : official journal of the Controlled Release Society.

[27]  M. Melancon,et al.  Cancer theranostics with near-infrared light-activatable multimodal nanoparticles. , 2011, Accounts of chemical research.

[28]  Da Xing,et al.  Gadolinium(III)-gold nanorods for MRI and photoacoustic imaging dual-modality detection of macrophages in atherosclerotic inflammation. , 2013, Nanomedicine.

[29]  C. Murphy,et al.  Gold nanoparticles are taken up by human cells but do not cause acute cytotoxicity. , 2005, Small.

[30]  J. Luong,et al.  Assessment of cytotoxicity of quantum dots and gold nanoparticles using cell-based impedance spectroscopy. , 2008, Analytical chemistry.

[31]  N. Rapoport,et al.  Doxorubicin as a molecular nanotheranostic agent: effect of doxorubicin encapsulation in micelles or nanoemulsions on the ultrasound-mediated intracellular delivery and nuclear trafficking. , 2010, Molecular pharmaceutics.

[32]  H. Maeda The enhanced permeability and retention (EPR) effect in tumor vasculature: the key role of tumor-selective macromolecular drug targeting. , 2001, Advances in enzyme regulation.

[33]  C. Xiong,et al.  Effective photothermal chemotherapy using doxorubicin-loaded gold nanospheres that target EphB4 receptors in tumors. , 2012, Cancer research.

[34]  Wei Lu,et al.  Photoacoustic imaging of living mouse brain vasculature using hollow gold nanospheres. , 2010, Biomaterials.