Non-invasive and low-artifact in vivo brain imaging by using a scanning acoustic-photoacoustic dual mode microscopy

Photoacoustic imaging is a potential candidate for in-vivo brain imaging, whereas, its imaging performance could be degraded by inhomogeneous multi-layered media, consisted of scalp and skull. In this work, we propose a low-artifact photoacoustic microscopy (LAPAM) scheme, which combines conventional acoustic-resolution photoacoustic microscopy with scanning acoustic microscopy to suppress the reflection artifacts induced by multi-layers. Based on similar propagation characteristics of photoacoustic signals and ultrasonic echoes, the ultrasonic echoes can be employed as the filters to suppress the reflection artifacts to obtain low-artifact photoacoustic images. Phantom experiment is used to validate the effectiveness of this method. Furthermore, LAPAM is applied for in-vivo imaging mouse brain without removing the scalp and the skull. Experimental results show that the proposed method successfully achieves the low-artifact brain image, which demonstrates the practical applicability of LAPAM. This work might improve the photoacoustic imaging quality in many biomedical applications, which involve tissue with complex acoustic properties, such as brain imaging through scalp and skull.

PEGPH20, a PEGylated Human Hyaluronidase, Induces Radiosensitization by Reoxygenation In Pancreatic Cancer Xenografts. A Molecular Imaging Study

PEGylated human hyaluronidase (PEGPH20) enzymatically depletes hyaluronan, an important component of the extracellular matrix, in tumors. The resultant improvement in vascular patency and perfusion has been shown to increase the delivery of therapeutic molecules. We show that PEGPH20 also improves the efficacy of radiation therapy in a human pancreatic adenocarcinoma BxPC3 mouse model overexpressing hyaluronan synthase 3 (BxPC3-HAS3) while exerting little effect on the corresponding wild type tumors. Mice overexpressing HAS3 developed fast growing, radiation resistant tumors that became rapidly more hypoxic as time progressed. Treatment with PEGPH20 increased survival times when used in combination with radiation therapy, significantly more than either radiation therapy or PEGPH20 alone. Radiosensitization in BxPC3-HAS3 tumors was attributed to an increase in local pO2 as studied by by EPR imaging. No effect on survival, radiation treatment, or pO2 was seen in wild type tumors after PEGPH20 treatment. Dynamic contrast enhanced (DCE) MRI and MRI based blood volume imaging showed improved perfusion/permeability and local blood volume, respectively, in BxPC3-HAS3 tumors after PEGPH20 treatment, accounting for the increase in tumor oxygenation. Photoacoustic imaging indicated immediate changes in tumor oxygenation after treatment. Metabolic MRI using hyperpolarized [1-13C] pyruvate suggested a metabolic shift towards decreased glycolytic flux after PEGPH20 treatment. In summary, the results showed that PEGPH20 may be useful for radiosensitization of pancreatic cancer but only in the subset of tumors with substantial hyaluronan accumulation and the response of the treatment may potentially be monitored non-invasive imaging of the hemodynamic and metabolic changes in the tumor microenvironment.

Design of Magnetic Nanoplatforms for Cancer Theranostics

Cancer is the top cause of death globally. Developing smart nanomedicines that are capable of diagnosis and therapy (theranostics) in one–nanoparticle systems are highly desirable for improving cancer treatment outcomes. The magnetic nanoplatforms are the ideal system for cancer theranostics, because of their diverse physiochemical properties and biological effects. In particular, a biocompatible iron oxide nanoparticle based magnetic nanoplatform can exhibit multiple magnetic–responsive behaviors under an external magnetic field and realize the integration of diagnosis (magnetic resonance imaging, ultrasonic imaging, photoacoustic imaging, etc.) and therapy (magnetic hyperthermia, photothermal therapy, controlled drug delivery and release, etc.) in vivo. Furthermore, due to considerable variation among tumors and individual patients, it is a requirement to design iron oxide nanoplatforms by the coordination of diverse functionalities for efficient and individualized theranostics. In this article, we will present an up–to–date overview on iron oxide nanoplatforms, including both iron oxide nanomaterials and those that can respond to an externally applied magnetic field, with an emphasis on their applications in cancer theranostics.

Photoacoustic imaging of 3D-printed vascular networks

Thrombosis in the circulation system can lead to major myocardial infarction and cardiovascular deaths. Understanding thrombosis formation is necessary for developing safe and effective treatments. In this work, using digital light processing (DLP)-based 3D printing, we fabricated sophisticated in vitro models of blood vessels with internal microchannels that can be used for thrombosis studies. In this regard, photoacoustic microscopy (PAM) offers a unique advantage for label-free visualization of the 3D-printed vessel models, with large penetration depth and functional sensitivity. We compared the imaging performances of two PAM implementations: optical-resolution PAM and acoustic-resolution PAM, and investigated 3D printed- vessel structures with different patterns of microchannels. Our results show that PAM can provide clear microchannel structures at depths up to 3.6 mm. We further quantified the blood oxygenation in the 3D-printed vascular models, showing that thrombi had lower oxygenation than the normal blood. We expect that PAM can find broad applications in 3D printing and bioprinting for in vitro studies of various vascular and other diseases.

Characterization of interconnectivity of gelatin methacrylate hydrogels using photoacoustic imaging

Hydrogels can provide a three-dimensional microenvironment for cells and thus serve as an extracellular matrix in a biofabrication process. The properties of hydrogels, such as their porosity and mechanical properties,...

Ionic Liquid Exfoliated Ti3C2Tx MXene Nanosheets for Photoacoustic Imaging and Synergistic Photothermal/ Chemotherapy of Cancer

Ti3C2Tx MXene is a new biocompatible, two-dimensional material with good photothermal effects, which shows great potential in cancer nano-drug research. In this study, a few-layer ionic liquid (IL)-Ti3C2Tx MXene nanosheets...