The blood–brain barrier (BBB) has a significant contribution to homeostasis and protection of the CNS. However, it also limits the crossing of therapeutics and thereby complicates the treatment of CNS disorders. To overcome this limitation, the use of nanocarriers for drug delivery across the BBB has recently been exploited. Nanocarriers can utilize different physiological mechanisms for drug delivery across the BBB and can be modified to achieve the desired kinetics and efficacy. Consequentially, several nanocarriers have been reported to act as functional nanomedicines in preclinical studies using animal models for human diseases. Given the rapid development of novel nanocarriers, this review provides a comprehensive insight into the most recent advancements made in nanocarrier-based drug delivery to the CNS, such as the development of multifunctional nanomedicines and theranostics.
Extracellular vesicles
(EVs) secreted by cancer cells provide an
important insight into cancer biology and could be leveraged to enhance
diagnostics and disease monitoring. This paper details a high-throughput
label-free extracellular vesicle analysis approach to study fundamental
EV biology, toward diagnosis and monitoring of cancer in a minimally
invasive manner and with the elimination of interpreter bias. We present
the next generation of our single particle automated Raman trapping
analysisSPARTAsystem through the development of a
dedicated standalone device optimized for single particle analysis
of EVs. Our visualization approach, dubbed dimensional reduction analysis
(DRA), presents a convenient and comprehensive method of comparing
multiple EV spectra. We demonstrate that the dedicated SPARTA system
can differentiate between cancer and noncancer EVs with a high degree
of sensitivity and specificity (>95% for both). We further show
that
the predictive ability of our approach is consistent across multiple
EV isolations from the same cell types. Detailed modeling reveals
accurate classification between EVs derived from various closely related
breast cancer subtypes, further supporting the utility of our SPARTA-based
approach for detailed EV profiling.
Vascular tissue engineering is an area of regenerative medicine that attempts to create functional replacement tissue for defective segments of the vascular network. One approach to vascular tissue engineering utilizes seeding of biodegradable tubular scaffolds with stem (and/or progenitor) cells wherein the seeded cells initiate scaffold remodeling and prevent thrombosis through paracrine signaling to endogenous cells. Stem cells have received an abundance of attention in recent literature regarding the mechanism of their paracrine therapeutic effect. However, very little of this mechanistic research has been performed under the aegis of vascular tissue engineering. Therefore, the scope of this review includes the current state of TEVGs generated using the incorporation of stem cells in biodegradable scaffolds and potential cell-free directions for TEVGs based on stem cell secreted products. The current generation of stem cell-seeded vascular scaffolds are based on the premise that cells should be obtained from an autologous source. However, the reduced regenerative capacity of stem cells from certain patient groups limits the therapeutic potential of an autologous approach. This limitation prompts the need to investigate allogeneic stem cells or stem cell secreted products as therapeutic bases for TEVGs. The role of stem cell derived products, particularly extracellular vesicles (EVs), in vascular tissue engineering is exciting due to their potential use as a cell-free therapeutic base. EVs offer many benefits as a therapeutic base for functionalizing vascular scaffolds such as cell specific targeting, physiological delivery of cargo to target cells, reduced immunogenicity, and stability under physiological conditions. However, a number of points must be addressed prior to the effective translation of TEVG technologies that incorporate stem cell derived EVs such as standardizing stem cell culture conditions, EV isolation, scaffold functionalization with EVs, and establishing the therapeutic benefit of this combination treatment.
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