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The first example of top-down proteomics of nanoparticle protein coronas using capillary isoelectric focusing-mass spectrometry. 

Abstract Nanomedicine technologies are being developed for the prevention, diagnosis, and treatment of cardiovascular disease (CVD), which is the leading cause of death worldwide. Before delving into the nuances of cardiac nanomedicine, it is essential to comprehend the fundamental sex‐specific differences in cardiovascular health. Traditionally, CVDs have been more prevalent in males, but it is increasingly evident that females also face significant risks, albeit with distinct characteristics. Females tend to develop CVDs at a later age, exhibit different clinical symptoms, and often experience worse outcomes compared to males. These differences indicate the need for sex‐specific approaches in cardiac nanomedicine. This Perspective discusses the importance of considering sex in the safety and therapeutic efficacy of nanomedicine approaches for the prevention, diagnosis, and treatment of CVD. 

Abstract Understanding the interaction between biological structures and nanoscale technologies, dubbed the nano-bio interface, is required for successful development of safe and efficient nanomedicine products. The lack of a universal reporting system and decentralized methodologies for nanomaterial characterization have resulted in a low degree of reliability and reproducibility in the nanomedicine literature. As such, there is a strong need to establish a characterization system to support the reproducibility of nanoscience data particularly for studies seeking clinical translation. Here, we discuss the existing key standards for addressing robust characterization of nanomaterials based on their intended use in medical devices or as pharmaceuticals. We also discuss the challenges surrounding implementation of such standard protocols and their implication for translation of nanotechnology into clinical practice. We, however, emphasize that practical implementation of standard protocols in experimental laboratories requires long-term planning through integration of stakeholders including institutions and funding agencies. 

Abstract Robust characterization of the protein corona—the layer of proteins that spontaneously forms on the surface of nanoparticles immersed in biological fluids—is vital for prediction of the safety, biodistribution, and diagnostic/therapeutic efficacy of nanomedicines. Protein corona identity and abundance characterization is entirely dependent on liquid chromatography coupled to mass spectroscopy (LC-MS/MS), though the variability of this technique for the purpose of protein corona characterization remains poorly understood. Here we investigate the variability of LC-MS/MS workflows in analysis of identical aliquots of protein coronas by sending them to different proteomics core-facilities and analyzing the retrieved datasets. While the shared data between the cores correlate well, there is considerable heterogeneity in the data retrieved from different cores. Specifically, out of 4022 identified unique proteins, only 73 (1.8%) are shared across the core facilities providing semiquantitative analysis. These findings suggest that protein corona datasets cannot be easily compared across independent studies and more broadly compromise the interpretation of protein corona research, with implications in biomarker discovery as well as the safety and efficacy of our nanoscale biotechnologies. 

Vascular restenosis is a major complication in recanalized arteries. Nanoparticles (NPs) have shown great promise as delivery systems in advancing strategies to treat such vascular anomalies. By enabling precise targeting, NPs can overcome the challenges of low drug efficacy and off-target effects. Here we present a biomimetic in vitro platform comprised of 3D bioprinting, nanomaterials, and perfusion technologies, to study the use of NP targeting to address endothelial overgrowth. We bioprinted 3D vascular channels at high fidelity, using gelatin methacrylate as bioink, with artery-like stiffness. Human endothelial cells (ECs) were used to endothelialize the printed channels. GFP-labelled superparamagnetic iron oxide NPs (SPIONs), loaded with the Rapamune anti-proliferative drug, were perfused through the bifurcated artery model at physiological rate. Computational modeling predicted greatest level of alterations in wall shear stress in the conduit’s junction with the artery, identifying this region prone to restenosis. A neodymium disc magnet was embedded in the printed tissue to attract the therapeutic SPIONs to the region of high risk. In vitro dynamic culture was conducted for 2 wks. We assessed cell viability, proliferation, and function using AlamarBlue and immunohistochemistry. Results showed significant targeted effect of NP delivery in reducing EC overgrowth. This platform enables design of precise targeting of therapeutics to treat a variety of cardiovascular diseases at a high spatial and temporal control.