Fergusonkelley0570
Nanoparticles offer great promise for more effective drug delivery. However, their particulate nature typically results in rapid systemic clearance by immune cells in blood. Currently, to understand these interactions, nanoparticle association is probed ex vivo with whole blood. While ex vivo assays give important information about the relative cell association, they do not consider changes in immune cell homeostasis or the complex mixing behavior that occurs in vivo. To address this, a nanoparticle in vivo immune-cell association assay is developed to study the in vivo association of unmodified and poly(ethylene glycol) modified liposomes with immune cells, and compared this to the ex vivo association in static whole blood. In vivo, it is observed that neutrophils play a significantly greater role in nanoparticle binding than suggested by ex vivo assays. The increased influence of neutrophils in vivo is largely due to a significant increase in number of circulating neutrophils after intravenous injection. Conversely, the number of circulating monocytes significantly decreased after intravenous injection, leading to significantly less total association of liposomes to monocytes compared to ex vivo. This novel in vivo immune cell binding assay sheds new light on the fate of nanoparticles following intravenous delivery.Extremity skeletal muscle injuries result in substantial disability. Current treatments fail to recoup muscle function, but properly designed and implemented tissue engineering and regenerative medicine techniques can overcome this challenge. In this study, a nanoengineered, growth factor-eluting bioink that utilizes Laponite nanoclay for the controlled release of vascular endothelial growth factor (VEGF) and a GelMA hydrogel for a supportive and adhesive scaffold that can be crosslinked in vivo is presented. The bioink is delivered with a partially automated handheld printer for the in vivo formation of an adhesive and 3D scaffold. The effect of the controlled delivery of VEGF alone or paired with adhesive, supportive, and fibrilar architecture has not been studied in volumetric muscle loss (VML) injuries. Upon direct in vivo printing, the constructs are adherent to skeletal muscle and sustained release of VEGF. The in vivo printing of muscle ink in a murine model of VML injury promotes functional muscle recovery, reduced fibrosis, and increased anabolic response compared to untreated mice. The in vivo construction of a therapeutic-eluting 3D scaffold paves the way for the immediate treatment of a variety of soft tissue traumas.Delays in language are a hallmark feature of Autism Spectrum Disorder (ASD). However, little is known about the predictive role of language developmental trajectories on ASD. The present study aimed at identifying early different language developmental profiles of infants at high familial risk for ASD (HR-ASD) and testing their predictive role on ASD symptoms at 2 years. learn more The role of gestures on socio-communicative skills has also been explored. Trajectories of expressive vocabulary were investigated in 137 HR-ASD infants at 12, 18, and, 24 months of age. Parents were requested to complete the Italian version of the MacArthur-Bates Communicative Development Inventory and ASD symptoms were measured by ADOS-2. Latent class growth analysis defined four trajectories above average language development group (above-average LD, 18.2%), normal language development group (NLD, 38.7%), late-onset language development group (late-onset LD, 11.7%), and a group of children with stable language delay (SLD, 31.4%). Results swith a stable language delay (SLD) trajectory showed more ASD symptoms later on. SLD infants produced fewer gestures compared to late-onset language development group that show more typical communicative skills.
We aim to broaden understanding of the perspectives of persons with arthritis on their use of wearables to self-monitor physical activity, through a synthesis of evidence from qualitative studies.
We conducted a systematic search of 5 databases (including Medline, CINAHL, and Embase) from inception to 2018. Eligible studies qualitatively examined the use of wearables from the perspectives of persons with arthritis. All relevant data were extracted and coded inductively in a thematic synthesis.
Of 4358 records retrieved, 7 articles were included. Participants used a wearable during research participation in 3 studies and as part of usual self-management in 2 studies. In remaining studies, participants were shown a prototype they did not use. Themes identified were 1) Potential to change dynamics in patient-health professional communication Articles reported a common opinion that sharing wearable data could possibly enable them to improve communication with health professionals; 2) Wearable-enabled self-ation.Gliomas remain difficult to treat because of their metastatic and recurrent nature and the existence of the blood-brain barrier (BBB), which impedes drug delivery. Microglia, the resident macrophages in the CNS, can be recruited by gliomas and can penetrate the tumor. In this study, microglia (BV2 cells) are used as transport vectors to deliver paclitaxel for the treatment of glioma. To avoid paclitaxel toxicity in microglia, liposomes are first employed to isolate the drug from BV2 cells. Dipalmitoyl phosphatidylserine (DPPS), as an "eat me" signal, is doped into liposomes to amplify their phagocytosis by microglia. This study demonstrates that engineered microglia can cross the BBB, independently migrate toward gliomas, and transfer cargo to glioma cells. Of note, extracellular vesicles and tunneling nanotubes are found to offer unique modes of cargo transportation between microglia and glioma cells. In vivo, the engineered drug-loaded microglia has a high ability to target the brain, penetrate glioma, and suppress tumor progression, supporting the notion that the use of engineered microglia is a potential strategy for the treatment of glioma. These findings present new opportunities for exploration into the use of microglia as transport vectors to deliver therapeutic agents through specific membrane nanotubes and vesicles.
