5 research outputs found
Gold nanoparticles and radiofrequency in experimental models for hepatocellular carcinoma
Hepatocellular carcinoma (HCC) is one of the most lethal and chemo-refractory cancers, clearly, alternative treatment strategies are needed. We utilized 10Â nm gold nanoparticles as a scaffold to synthesize nanoconjugates bearing a targeting antibody (cetuximab, C225) and gemcitabine. Loading efficiency of gemcitabine on the gold nanoconjugates was 30%. Targeted gold nanoconjugates in combination with RF were selectively cytotoxic to EGFR expressing Hep3B and SNU449 cells when compared to isotype particles with/without RF (PÂ <Â 0.05). In animal experiments, targeted gold nanoconjugates halted the growth of subcutaneous Hep3B xenografts in combination with RF exposure (PÂ <Â 0.05). These xenografts also demonstrated increased apoptosis, necrosis and decreased proliferation compared to controls. Normal tissues were unharmed. We have demonstrated that non-invasive RF-induced hyperthermia when combined with targeted delivery of gemcitabine is more effective and safe at dosages ~Â 275-fold lower than the current clinically-delivered systemic dose of gemcitabine
Citrate-Capped Gold Nanoparticle Electrophoretic Heat Production in Response to a Time-Varying Radio-Frequency Electric Field
The evaluation of heat production from gold nanoparticles
(AuNPs)
irradiated with radio-frequency (RF) energy has been problematic due
to Joule heating of their background ionic buffer suspensions. Insights
into the physical heating mechanism of nanomaterials under RF excitations
must be obtained if they are to have applications in fields such as
nanoparticle-targeted hyperthermia for cancer therapy. By developing
a purification protocol that allows for highly stable and concentrated
solutions of citrate-capped AuNPs to be suspended in high-resistivity
water, we show herein, for the first time, that heat production is
only evident for AuNPs of diameters ≤10 nm, indicating a unique
size-dependent heating behavior not previously observed. Heat production
has also shown to be linearly dependent on both AuNP concentration
and total surface area and was severely attenuated upon AuNP aggregation.
These relationships have been further validated using permittivity
analysis across a frequency range of 10 MHz–3 GHz as well as
static conductivity measurements. Theoretical evaluations suggest
that the heating mechanism can be modeled by the electrophoretic oscillation
of charged AuNPs across finite length scales in response to a time-varying
electric field. It is anticipated these results will assist future
development of nanoparticle-assisted heat production by RF fields
for applications such as targeted cancer hyperthermia
Gold nanoparticles and radiofrequency in experimental models for hepatocellular carcinoma
Citrate-Capped Gold Nanoparticle Electrophoretic Heat Production in Response to a Time-Varying Radio-Frequency Electric Field
The evaluation of heat production from gold nanoparticles (AuNPs) irradiated with radio-frequency (RF) energy has been problematic due to Joule heating of their background ionic buffer suspensions. Insights into the physical heating mechanism of nanomaterials under RF excitations must be obtained if they are to have applications in fields such as nanoparticle-targeted hyperthermia for cancer therapy. By developing a purification protocol that allows for highly stable and concentrated solutions of citrate-capped AuNPs to be suspended in high-resistivity water, we show herein, for the first time, that heat production is only evident for AuNPs of diameters ≤10 nm, indicating a unique size-dependent heating behavior not previously observed. Heat production has also shown to be linearly dependent on both AuNP concentration and total surface area and was severely attenuated upon AuNP aggregation. These relationships have been further validated using permittivity analysis across a frequency range of 10 MHz–3 GHz as well as static conductivity measurements. Theoretical evaluations suggest that the heating mechanism can be modeled by the electrophoretic oscillation of charged AuNPs across finite length scales in response to a time-varying electric field. It is anticipated these results will assist future development of nanoparticle-assisted heat production by RF fields for applications such as targeted cancer hyperthermia