In vivo monitoring of liposomal release in tumours following ultrasound stimulation.

Dioeleoylphosphatidylethanolamine (DOPE)-based liposomes were recently reported as a new class of liposomes for ultrasound (US)-mediated drug delivery. The liposomes showed both high stability and in vitro US-mediated drug release (sonosensitivity). In the current study, in vivo proof-of-principle of US triggered release in tumoured mice was demonstrated using optical imaging. Confocal non-thermal US was used to deliver cavitation to tumours in a well-controlled manner. To detect in vivo release, the near infrared fluorochrome Al (III) Phthalocyanine Chloride Tetrasulphonic acid (AlPcS4) was encapsulated into both DOPE-based liposomes and control liposomes based on hydrogenated soy phosphatidylcholine (HSPC). Encapsulation causes concentration dependent quenching of fluorescence that is recovered upon AlPcS4 release from the liposomes. Exposure of tumours to US resulted in a significant increase in fluorescence in mice administered with DOPE-based liposomes, but no change in the mice treated with HSPC-based liposomes. Thus, DOPE-based liposomes showed superior sonosensitivity compared to HSPC-based liposomes in vivo.

Assessment of liposome biodistribution by non-invasive optical imaging: a feasibility study in tumour-bearing mice.

Liposomal encapsulation of cytostatics improves drug delivery to tumour tissue and reduces dose-limiting systemic toxicities. Development and evaluation of new liposome formulations is time consuming and costly with high demands for experimental animals. A faster and less demanding means of comparing several product candidates may be provided by use of non-invasive methods for assessing pharmacokinetics and biodistribution. In this study we have evaluated the feasibility of using small animal fluorescence optical imaging as a strategy to study liposome accumulation in tumours. Liposomal doxorubicin (Caelyx) was labelled with a lipophilic carbocyanine tracer and administered to tumour-bearing mice. Subsequently, the in vivo distribution of the labelled liposomes was followed over time by fluorescent optical imaging. The results revealed a gradual increase in tumour fluorescence, indicating accumulation of the liposomes reaching plateau levels at 48 h post injection. However, due to loss of dye from liposomes during circulation combined with substantial scattering and absorption of in vivo fluorescent signal, reliable quantitative correlation between the biodistribution profile of the labelled liposomes and doxorubicin could not be obtained.

Liposomal doxorubicin improves radiotherapy response in hypoxic prostate cancer xenografts.

BACKGROUND: Tumor vasculature frequently fails to supply sufficient levels of oxygen to tumor tissue resulting in radioresistant hypoxic tumors. To improve therapeutic outcome radiotherapy (RT) may be combined with cytotoxic agents. METHODS: In this study we have investigated the combination of RT with the cytotoxic agent doxorubicin (DXR) encapsulated in pegylated liposomes (PL-DXR). The PL-DXR formulation Caelyx was administered to male mice bearing human, androgen-sensitive CWR22 prostate carcinoma xenografts in a dose of 3.5 mg DXR/kg, in combination with RT (2 Gy/day × 5 days) performed under normoxic and hypoxic conditions. Hypoxic RT was achieved by experimentally inducing tumor hypoxia by clamping the tumor-bearing leg five minutes prior to and during RT. Treatment response evaluation consisted of tumor volume measurements and dynamic contrast-enhanced magnetic resonance imaging (DCE MRI) with subsequent pharmacokinetic analysis using the Brix model. Imaging was performed pre-treatment (baseline) and 8 days later. Further, hypoxic fractions were determined by pimonidazole immunohistochemistry of excised tumor tissue. RESULTS: As expected, the therapeutic effect of RT was significantly less effective under hypoxic than normoxic conditions. However, concomitant administration of PL-DXR significantly improved the therapeutic outcome following RT in hypoxic tumors. Further, the pharmacokinetic DCE MRI parameters and hypoxic fractions suggest PL-DXR to induce growth-inhibitory effects without interfering with tumor vascular functions. CONCLUSIONS: We found that DXR encapsulated in liposomes improved the therapeutic effect of RT under hypoxic conditions without affecting vascular functions. Thus, we propose that for cytotoxic agents affecting tumor vascular functions liposomes may be a promising drug delivery technology for use in chemoradiotherapy.

Sonosensitive dioleoylphosphatidylethanolamine-containing liposomes with prolonged blood circulation time of doxorubicin.

Ultrasound sensitive (sonosensitive) liposomes represent a drug delivery system designed for releasing a drug load upon exposure to ultrasound (US). Inclusion of dioleoylphosphatidylethanolamine (DOPE) in liposome membranes was previously shown to induce sonosensitivity. Long blood circulation time of the liposomal drug is required for high tumour uptake and efficient US-mediated drug delivery. In this study, blood pharmacokinetics of DOPE-based liposomal doxorubicin (DXR) were evaluated in non-tumoured mice. A markedly faster blood clearance of DXR was observed for DOPE-rich liposomes compared to Caelyx® (standard liposomal DXR). Subsequently, liposome membrane composition was altered to improve drug retention in the bloodstream, whilst maintaining sonosensitivity. Formulations with reduced blood clearance of DXR were obtained by reducing the content of DOPE from 62 to 32 or 25 mol%. These formulations showed long blood circulation time, as approximately 20% of the administered DXR dose was present in the bloodstream 24 h after intravenous injection. The reduction in liposomal DOPE content did not significantly reduce US-mediated DXR release in vitro, indicating that DOPE is a potent modulator of sonosensitivity. The novel liposome formulations, containing moderate amounts of DOPE, displayed similar blood pharmacokinetic profiles as standard liposomal DXR, but a markedly improved sonosensitivity.

Ultrasound enhanced antitumor activity of liposomal doxorubicin in mice.

Liposomal encapsulation of doxorubicin (DXR) improves tumor accumulation and reduces adverse effects. One possible strategy for further optimization of this delivery technology would be to design the liposome carrier to release its content within the tumor tissue in response to specific stimuli such as ultrasound (US). In this study, the tumor uptake properties and therapeutic efficacy of 1,2 distearoyl-sn-glycero-3-phosphatidylethanolamine-based liposomes containing DXR were investigated in nude mice bearing tumor xenografts. The liposomal DXR formulation alone showed no inhibitory effect on tumor growth. However, upon exposure to low frequency US in situ inhibition of tumor growth was demonstrated.