Photoacoustic (PA) imaging has been considered an attractive imaging modality for sensitive and in-depth imaging of biomolecules with a high resolution in vivo. PA imaging probes utilizing fluorescence dyes, including indocyanine green (ICG), have been proposed to enhance PA signal intensity. On the other hand, nanomicelles modified with polysarcosine (PSar), a biocompatible hydrophilic polymer, on their surface have previously achieved rapid tumor uptake, suggesting active transport of PSar into tumor tissues. Thus, we hypothesized that PSar-based materials might be utilized as diagnostic probes for targeting tumors and therefore evaluated the potential of PSar labeled with an ICG derivative, ICG-PSar, as a PA imaging probe for targeting cancer. In this study, ICG-PSars with differing molecular weights (10, 20, and 30 kDa) were synthesized. In vitro cellular uptake studies using ICG-PSar demonstrated rapid uptake in colon26 tumor cells partially via macropinocytosis-mediated endocytosis. In vivo fluorescence imaging and biodistribution study indicated that ICG-PSar30k exhibited high accumulation in the tumor (8.4% dose/g), with high tumor-to-blood ratios reaching 4.6 at 24 h post injection of the probe. Finally, in vivo PA imaging studies showed that PA signal increased in tumors (251%) but not in blood vessels, achieving high contrast tumor imaging at 24 h after ICG-PSar30k probe injection. These results suggest that ICG-PSar has potential as a tumor-targeting PA imaging probe.
Brachytherapy is a type of radiotherapy wherein titanium capsules containing therapeutic radioisotopes are implanted within tumor tissues, enabling high-dose radioirradiation to tumor tissues around the seeds. Although marked therapeutic effects have been demonstrated, brachytherapy needs a complicated implantation technique under general anesthesia and the seeds could migrate to other organs. The aim of this study was to establish a novel brachytherapy using biocompatible, injectable thermoresponsive polymers (polyoxazoline [POZ]) labeled with Y, which can self-aggregate above a specific transition temperature (Tt), resulting in long-term intratumoral retention of radioactivity and therapeutic effect. Therefore, we evaluated the tumor retention of radiolabeled POZ derivatives and their therapeutic effects. Using oxazoline derivatives with ethyl (Et), isopropyl (Isp), and propyl (Pr) side chains, we synthesized EtPOZ, IspPOZ, Isp-PrPOZ (heteropolymer), and PrPOZ and measured their characteristic Tts. The intratumoral retention of In-labeled POZ was evaluated until 7 d after injection in nude mice bearing PC-3 human prostate cancer. The intratumoral localization ofIn-labeled POZ derivatives was investigated by an autoradiographic study. Furthermore, a therapeutic study using Y-labeled Isp-PrPOZ was performed, and tumor growth and survival rate were evaluated. The Tts of EtPOZ, IspPOZ, Isp-PrPOZ, and PrPOZ (∼20 kDa) were greater than 70°C, 34°C, 25°C, and 19°C, respectively. In the intratumoral injection study, Isp-PrPOZ and PrPOZ (2,000 μM) with Tts lower than tumor temperature (33.5°C under anesthesia) showed a significantly higher retention of radioactivity at 1 d after injection (73.6% and 73.9%, respectively) than EtPOZ (5.6%) and IspPOZ (15.8%). Even at low injected dose (100 μM), Isp-PrPOZ exhibited high retention (68.3% at 1 d). The high level of radioactivity of Isp-PrPOZ was retained in the tumor 7 d after injection (69.5%). The autoradiographic study demonstrated that the radioactivity of In-labeled Isp-PrPOZ and PrPOZ was localized in a small area. In the therapeutic study usingY-labeled Isp-PrPOZ, significant suppression of tumor growth and prolonged survival rate were achieved in an injection dose-dependent manner compared with that observed for the vehicle-injected group and nonradioactive Isp-PrPOZ-injected group. The injectableY-labeled Isp-PrPOZ was retained for a prolonged period within tumor tissues via self-aggregation and exhibited marked therapeutic effect, suggesting its usefulness for brachytherapy.
The scFv-IONPs enabled HER2-specific tumor MR imaging, suggesting the potential of scFv-IONPs as a robust HER2-targeted MR contrast agent.
In order to develop a radiopharmaceutical for internal radiotherapy that had a high anticancer effect while exposing normal tissues to low radiation levels, we synthesized a radiolabeled polyoxazoline (POZ), a thermoresponsive polymer, and established a novel drug delivery system for targeting tumors by accelerating the accumulation of the radiolabeled POZ via self-aggregation under hyperthermic (42-43 °C) conditions. By living-cationic polymerization using 2-ethyl-2-oxazoline and 2-isopropyl-2-oxazoline, POZ derivatives (Et-IspPOZ) (10, 20, and 30 kDa) with lower critical solution temperatures (LCSTs) of 37-38 °C were synthesized; the POZ derivatives were soluble at the body temperature but self-aggregated upon heat treatment (42-43 °C). Next, the indium-111 (In)-labeled Et-IspPOZ was prepared, and the effect of molecular weight and injected POZ dose on the accumulation of radioactivity in the tumors was investigated upon intravenous injection of probes under hyperthermic conditions in colon 26-bearing mice. The uptake of radioactivity in tumors was increased when the molecular weight of POZ was greater than 20 kDa, while it was independent of the injected POZ dose (4-40 nmol). The amount of radioactivity retained in the tumor did not change for up to 3 h after exposure to heat treatment was stopped. Furthermore, the tumor uptake of the Et-IspPOZ derivative with an LCST greater than 42 °C was significantly lower than that of Et-IspPOZ, which had an LCST of 37-38 °C, suggesting the involvement of the self-aggregation of POZ on tumor uptake. Finally, the intratumoral localization of fluorescence-labeled Et-IspPOZ was evaluated using in vivo confocal laser microscopy. Many bright fluorescence spots were observed in the heat-treated tumors nearby and within blood vessels. In conclusion, the high tumor uptake of radiolabeled Et-IspPOZ was elucidated under hyperthermic conditions; thereby, the possibility of developing a novel internal radiotherapy using radiolabeled POZ derivatives was demonstrated.
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