Near-infrared narrow-band imaging of gold/silica nanoshells in tumors

Puvanakrishnan, Priyaveena

03 September 2009

Gold nanoshells (GNS) are a new class of nanoparticles that can be optically tuned to scatter or absorb light from the near-ultraviolet to near-infrared (NIR) region by varying the core (dielectric silica) /shell (gold) ratio. In addition to spectral tunability, GNS are inert and bioconjugatable making them potential labels for in vivo imaging and therapy of tumors. We report the use of GNS as exogenous contrast agents for enhanced visualization of tumors using narrow band imaging (NBI). NBI takes advantage of the strong NIR absorption of GNS to distinguish between blood and nanoshells in the tumor by imaging in narrow wavelength bands in the visible and NIR, respectively. Using tissue-simulating phantoms, we determined the optimum wavelengths to enhance contrast between blood and GNS. We then used the optimum wavelengths for ex-vivo imaging of tumors extracted from human colon cancer xenograft bearing mice injected with GNS. Systemically delivered GNS accumulated passively in tumor xenografts by enhanced permeability and retention (EPR) effect. Ex-Vivo NBI of tumor xenografts demonstrated tumor specific heterogeneous distribution of GNS with a clear distinction from the tumor vasculature. The results of the present study demonstrate the feasibility of using GNS as contrast agents to visualize tumor tissues using NBI technique. / text

cancer

narrow-band imaging

Gold nanoshells

Synthesis of Gold Nanostructures with Optical Properties within the Near-Infrared Window for Biomedical Applications

Garcia Soto, Mariano de Jesús

January 2014

The work reported in this dissertation describes the design and synthesis of different gold nanoshells with strong absorption coefficients at the near-infrared region (NIR) of the spectrum, and includes preliminary studies of their use for the photo-induced heating of pancreatic cancer cells and ex vivo tissues. As the emphasis was on gold nanoshells with maximum extinctions located at 800 nm, the methods explored for their synthesis led us to the preparation of silica-core and hollow gold nanoshells of improved stability, with maximum extinctions at or beyond the targeted within the near-infrared window. The synthesis of silica-core gold nanoshells was investigated first given its relevance as one of the pioneering methods to produce gold nanostructures with strong absorption and scattering coefficients in the visible and the near-infrared regions of the spectrum. By using a classical method of synthesis, we explored the aging of the precursor materials and the effect of using higher concentrations than the customary for the reduction of gold during the shell growth. We found that the aging for one week of the as-prepared or purified precursors, namely, the gold cluster suspensions, and the seeded silica particles, along with higher concentrations of gold in the plating solution, produced fully coated nanoshells of 120 nm in size with smooth surfaces and maximum extinctions around 800 nm. Additional work carried out to reduce the time and steps in the synthesis of silica-core gold nanoshells, led us to improve the seeding step by increasing the ionic strength of the cluster suspension, and also to explore the growth of gold on tin-seeded silica nanoparticles. The synthesis of hollow gold nanoshells (HGS) of with maximum extinctions at the NIR via the galvanic replacement of silver nanoparticles for gold in solution was explored next. A first method explored led us to obtain HGS with maximum extinctions between 650 and 800 nm and sizes between 30 and 80 nm from silver nanoparticles, which were grown by the addition of silver nitrate and a mild reducer. We developed a second method that led us to obtain HGS with maximum extinctions between 750 and 950 nm by adjusting the pH of the precursor solution of the silver particles without much effort or additional steps. The last part of this work consisted in demonstrating the photo-induced heating of two biological systems containing HGS. Photothermal therapy studies of immobilized PANC1 pancreas cancer cells in well-plates were carried out with functionalized HGS. We found that cells exposed to HGS remained viable after incubation. Moreover, the cells incubated with HGS modified with mercaptoundecanoic acid and folic acid turned non-viable after being irradiated with a laser at 800 nm. The other study consisted in the laser-induced heating between 750 and 1000 nm of ex vivo tissues of chicken and pork with nanoshells injected. In comparison with non-injected tissues, it was found that the temperature at the irradiated areas with HGS increased more than 10 °C. Moreover, the extent of the heated area was broader when the laser was used at wavelengths beyond 900 nm, suggesting that the heating was due to the radiation absorbed and transformed into heat primarily by the HGS and at a lesser extent by the water in the tissue.

Near-infrared window

Photo-induced heating

Silica-core gold nanoshells

Chemical Engineering

Hollow gold nanoshells

Understanding the Role of Colloidal Particles in Electroporation Mediated Delivery

Peterson, Alisha

01 January 2015

Electroporation (EP) is a physical non-viral technique used to deliver therapeutic molecules across the cell membrane. During electroporation an external electric field is applied across a cell membrane and it causes pores to form. These pores then allow the surrounding media containing the therapeutics to diffuse across the membrane. This technique has been specifically studied as a promising gene and drug delivery system. Colloidal particles have also proven to be promising for a variety of biological applications including molecular delivery, imaging, and tumor ablation, due to their large surface area and tunable properties. In more recent years researchers have explored the use of both electroporation and particles simultaneously. In this research, the main objective was to investigate and determine the role of sub-micron particles in the electroporation process. Presented in this dissertation are results from the synthesis and characterization of colloidal particles of various sizes and different compositions. The use of these dielectric and metallic particles during in vitro electroporation were investigated along with various other electrical parameters associated with EP such as pulse length, number of pulses, and field strength. Computationally, aspects such as particle composition and particle concentration were explored in an attempt to predict experimental outcomes.

Electric Fields

Fluorometric Assay

Silica

Gold Nanoshells

Electric Field Simulations

Materials Science and Engineering

Gold nanoshells for surface enhanced Raman spectroscopy and drug delivery

January 2012

Gold nanoshells are tunable plasmonic nanostructures consisting of spherical silica cores wrapped with thin layer of Au. Based on the size of the Au layer with respect to the silica core, gold nanoshells can resonantly absorb or scatter light at any wavelength on the visible or infrared. On resonance, gold nanoshells interact strongly with light to give rise to collective oscillations of the free electrons against the background of the ionic core, phenomena known as localized surface plasmons. The free electron oscillation creates surface plasmon multimodes of various orders. As a result, the average local near field surrounding the Au nanoshell is enhanced. The local field enhancement has been extensively used in different applications. In this work, the local near-field is used to enhance the Raman spectroscopy of DNA and explore the different modes attributed to the base composition and structure of the DNA sequence. We showed that urface enhanced Raman spectroscopy of DNA is dominated by the adenine modes regardless of the base composition of the DNA sequence, a property that we have used to develop a DNA label-free detection system. As absorbers, plasmon-resonant Au nanoshells can convert absorbed light into heat. As a consequence, the temperature on the Au nanoshell surface increases dramatically. This property is used to light-trigger the release of variety of therapeutic molecules such as single stranded DNA, siRNA and small molecules. We demonstrated that the local heat can be used to dehybridize double stranded DNA attached to the Au surface via a thiol moiety on one of the DNA strands. The complementary sequence (therapeutic sequence) is released at temperature lower than the standard melting temperature of same DNA sequence. Moreover, small molecules (DAPI) which were initially intercalated on the double stranded DNA attached to the Au surface were successfully released due to the heat generated around the nanoshell surface. Finally, siRNA molecules were also released using a different system made of PLL (polylysine) attached to Au nanoshells. The electrostatic interaction between the negatively charged siRNA and the positively charged PLL was overcome by the thermal perturbation causing the siRNA to be released. In vitro experiments successfully showed the release of siRNA, single stranded DNA and small molecules.

Health and environmental sciences

Applied sciences

Pure sciences

Gold nanoshells

Drug delivery

Drug release

DNA detection

Plasmonics

Physical chemistry

Pharmacy sciences

Nanotechnology