Nidal Muhanna scite author profile

PEGylation (PEG) is the most commonly adopted strategy to prolong nanoparticles' vascular circulation by mitigating the reticuloendothelial system uptake. However, there remain many concerns in regards to its immunogenicity, targeting efficiency, etc., which inspires pursuit of alternate, non-PEGylated systems. We introduced here a PEG-free, porphyrin-based ultrasmall nanostructure mimicking nature lipoproteins, termed PLP, that integrates multiple imaging and therapeutic functionalities, including positron emission tomography (PET) imaging, near-infrared (NIR) fluorescence imaging and photodynamic therapy (PDT). With an engineered lipoprotein-mimicking structure, PLP is highly stable in the blood circulation, resulting in favorable pharmacokinetics and biodistribution without the need of PEG. The prompt tumor intracellular trafficking of PLP allows for rapid nanostructure dissociation upon tumor accumulation to release monomeric porphyrins to efficiently generate fluorescence and photodynamic reactivity, which are highly silenced in intact PLP, thus providing an activatable mechanism for low-background NIR fluorescence imaging and tumor-selective PDT. Its intrinsic copper-64 labeling feature allows for noninvasive PET imaging of PLP delivery and quantitative assessment of drug distribution. Using a clinically relevant glioblastoma multiforme model, we demonstrated that PLP enabled accurate delineation of tumor from surrounding healthy brain at size less than 1 mm, exhibiting the potential for intraoperative fluorescence-guided surgery and tumor-selective PDT. Furthermore, we demonstrated the general applicability of PLP for sensitive and accurate detection of primary and metastatic tumors in other clinically relevant animal models. Therefore, PLP offers a biomimetic theranostic nanoplatform for pretreatment stratification using PET and NIR fluorescence imaging and for further customized cancer management via imaging-guided surgery, PDT, or/and potential chemotherapy.

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Activation of hepatic stellate cells after phagocytosis of lymphocytes: A novel pathway of fibrogenesis

Muhanna

et al. 2008

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H epatic fibrosis associated with inflammatory cell infiltration is a prominent feature of persistent infection by hepatitis B virus (HBV) and hepatitis C virus (HCV). The hepatic stellate cell (HSC) has assumed a central role in this response after its activation by inflammatory cytokines and mediators. [1][2][3][4][5] The cellmediated immune response after viral hepatitis reflects the activity of CD4ϩ helper T and CD8ϩ cytotoxic T

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Nidal Muhanna

Anti-fibrotic activity of NK cells in experimental liver injury through killing of activated HSC

A PEGylation-Free Biomimetic Porphyrin Nanoplatform for Personalized Cancer Theranostics

Activation of hepatic stellate cells after phagocytosis of lymphocytes: A novel pathway of fibrogenesis

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