Most
treatments for spinal cancer are accompanied by serious side
effects including subsequent tumor recurrence, spinal cord compression,
and tissue adhesion, thus a highly effective treatment is crucial
for preserving spinal and neurological functionalities. Herein, trilayered
electrospun doxorubicin@bovine serum albumin/poly(ε-caprolactone)/manganese
dioxide (DOX@BSA/PCL/MnO2) nanofibers with excellent antiadhesion
ability, dual glutathione/hydrogen peroxide (GSH/H2O2) responsiveness, and cascade release of Mn2+/DOX
was fabricated for realizing an efficient spinal tumor therapy. In
detail, Fenton-like reactions between MnO2 in the fibers
outermost layer and intra-/extracellular glutathione within tumors
promoted the first-order release of Mn2+. Then, sustained
release of DOX from the fibers’ core layer occurred along with
the infiltration of degradation fluid. Such release behavior avoided
toxic side effects of drugs, regulated inflammatory tumor microenvironment,
amplified tumor elimination efficiency through synergistic chemo-/chemodynamic
therapies, and inhibited recurrence of spinal tumors. More interestingly,
magnetic resonance and photoacoustic dual-modal imaging enabled visualizations
of tumor therapy and material degradation in vivo, achieving rapid pathological analysis and diagnosis. On the whole,
such versatile hierarchical-structured nanofibers provided a reference
for rapid and potent theranostic of spinal cancer in future clinical
translations.
Conventional detection methods for intersection traffic flow heavily rely on fixed-location inductive loop, video image processing, infared, and microwave radar detectors. The emerging connected vehicles (CV) technologies can potentially reduce such dependencies on conventional vehicle detectors with the vehicle-to-cloud (V2C) CV data. This paper proposes an analytical method for traffic flow estimation in urban arterial corridors based on CV trajectories collected through V2C communication. Different from the existing single-intersection models, the proposed model considers traffic states and the traffic signal coordination among adjacent intersections, therefore, can capture the delay and queuing dynamics in arterial corridors. The queue spillback phenomenon is explicitly considered by applying the shockwave theory. The proposed model is evaluated based on real-world vehicle trajectory data from the DiDi platform collected on an arterial network in Chengdu, China with a penetration rate of less than 10% of the overall traffic. The flow estimation results are compared with traffic counts collected from video detectors. The model parameters are calibrated with more than 300,000 GPS points during a typical workday and tested on a different workday. The evaluation results show a mean absolute percentage error within the range of 4–7% among all intersections, outperforming the results generated by the existing single-intersection model. The results indicate the promising potential of using the proposed methods to evaluate intersection performance without heavy investment in on-site detectors.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.