This review provides a perspective on porous silicon (pSi)-based nanomaterials including nanoparticles, nanowires, and thin films, that are currently being used in advanced therapy, imaging, and sensing, with a focus on their effective use in future clinical settings. The achievement of both controlled geometry and architecture, and surface chemistry motifs, are presented as the two key parameters that dictate the nature of interactions with the biological entities. The authors discuss the role of the degradation kinetics in a biological environment into nontoxic by-products. pSi is presented as increasingly fulfilling a central task in various biomedical applications and clinical settings, owing to its unique physiochemical properties.
The androgen receptor (AR) is the key oncogenic driver of prostate cancer and despite implementation of novel AR targeting therapies, patient outcomes for metastatic disease remain dismal. There is an urgent need to better understand androgen regulated cellular processes, in order to more effectively target the AR-dependence of prostate cancer cells through new therapeutic vulnerabilities. Transcriptomic studies have consistently identified lipid metabolism as a hallmark of enhanced AR signaling in prostate cancer, however the relationship between AR and the lipidome remain undefined. Using mass spectrometrybased lipidomics, this study revealed increased fatty acyl chain length in phospholipids from prostate cancer cells and patient-derived explants as one of the most striking androgenregulated changes to lipid metabolism. Potent and direct AR-mediated induction of ELOVL Fatty Acid Elongase 5 (ELOVL5), an enzyme that catalyzes fatty acid elongation, was demonstrated in prostate cancer cells, xenografts and clinical tumors. Assessment of mRNA and protein in large-scale datasets revealed ELOVL5 as the predominant ELOVL expressed in both primary and metastatic prostate cancer, and upregulated compared to non-malignant prostate. ELOVL5 depletion by siRNA markedly altered mitochondrial function to induce oxidative stress, resulting in significant inhibition of prostate cancer cell viability, 3D growth, and in vivo tumor growth and metastasis. Supplementation with the monounsaturated fatty acid cis-vaccenic acid, a direct product of ELOVL5 elongation, reversed the oxidative stress and associated cell viability caused by ELOVL5 knockdown. We have identified lipid elongation as a pro-survival metabolic pathway in prostate cancer that is androgenregulated, critical for metastasis and targetable via ELOVL5.
Gene silencing by RNA interference is a powerful technology with broad applications. However, this technology has been hampered by the instability of small interfering RNA (siRNA) molecules in physiological conditions and their inefficient delivery into the cytoplasm of target cells. Porous silicon nanoparticles have emerged as a potential delivery vehicle to overcome these limitationsbeing able to encapsulate RNA molecules within the porous matrix and protect them from degradation. Here, key variables were investigated that influence siRNA loading into porous silicon nanoparticles. The effect of modifying the surface of porous silicon nanoparticles with various amino-functional molecules as well as the effects of salt and chaotropic agents in facilitating siRNA loading was examined. Maximum siRNA loading of 413 μg/(mg of porous silicon nanoparticles) was found when the nanoparticles were modified by a fourth generation polyamidoamine dendrimer. Low concentrations of urea or salt increased loading capacity: an increase in RNA loading by 19% at a concentration of 0.05 M NaCl or 21% at a concentration of 0.25 M urea was observed when compared to loading in water. Lastly, it was demonstrated that dendrimer-functionalized nanocarriers are able to deliver siRNA against ELOVL5, a target for the treatment of advanced prostate cancer.
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