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Hot-stage polarized microscopy (HSM) revealed PVA's melt miscibility only with MAN and SOR, while melt flow index (MFI) measurements showed that the use of MAN, SOR and PEG400 resulted in a significant improvement of PVA's melt flow properties. Finally, MD simulations were in close agreement with the experimental observations, indicating that they can be considered as a promising tool for the theoretical modelling of such systems. A facile approach was developed to synthesize an innovative hyaluronic acid-modified carbon dot-doxorubicin nanoparticles drug delivery platform. CD44 targeted HA-modified carbon dots (HA-CDs) were synthesized as carrier by one-step hydrothermal treatment within one hour with citric acid and branch-PEI as core carbon source. HA not only functioned as carbon dot component but also as hydrophilic group and targeting ligand of this system. The as-prepared HA-CDs were then loaded with doxorubicin (HA-CD@p-CBA-DOX) via an acid-cleavable bond, which released drug in a pH-responsive manner. In in vitro experiments, HA-CD@p-CBA-DOX displayed good hemocompatibility and serum stability, while exhibited high cytotoxicity on 4T1 cells. The confocal laser scanning microscopy and flow cytometry results demonstrated that DOX-loaded nanoparticles were internalized by 4T1 cells via HA-mediated CD44-targeting effect. The enhanced in vivo tumor accumulation of HA-CD@p-CBA-DOX was testified by live imaging. Compared with free DOX, superior in vivo anti-tumor efficacy of HA-CD@p-CBA-DOX was observed in both heterotopic and orthotopic 4T1 cell tumor models. Furthermore, blood hematology and blood biochemistry analysis demonstrated that HA-CD@p-CBA-DOX did not induce noticeable toxicity, which further confirmed the good biocompatibility of HA-CD@p-CBA-DOX. The formulated HA-CD@p-CBA-DOX provides an alternative strategy for targeted breast cancer therapy. The development of small molecule anticancer drugs, with low water solubility and high toxicity, into polymeric prodrugs has developed into a promising strategy in clinical application. In this study, we synthesized a novel G3-C12-mediated esterase-sensitive tumor-targeting polymeric prodrug of camptothecin (CPT), P(OEGMA-co-CPT-co-G3-C12), and explored its anticancer activity against androgen-independent prostate cancer in vitro and in vivo. Compared to free CPT, the multifunctional polymeric prodrug demonstrated improved water solubility and stability, higher intracellular uptake, and enhanced cytotoxicity in DU145 cells in vitro. Furthermore, it displayed an improved accumulation in the tumor and an enhanced anticancer activity in vivo. this website Hence, P(OEGMA-co-CPT-co-G3-C12) could be a promising drug in the treatment of androgen-independent prostate cancer. Roller compaction is a continuous dry granulation process, in which powder is compressed by two counter-rotating rollers. During this process, the powder feeding to the compaction zone has a significant effect on product quality. This work investigates the flow of powder from the feeding zone to the compaction zone using online infrared thermography as Process Analytical Technology (PAT) which is achieved via a specially built cheek plate (side-sealing). The powder undergoes increasing stress from the rollers when it is approaching the minimum gap of the compaction zone, which can be indirectly monitored by measuring the powder temperature. The online monitoring of the powder flow during the roller compaction helps locate the nip region and identify the effect of different roller forces on the temperature of the feeding powder. The results show that the nip region can be identified by analysing the temperature profiles from the feeding to the compaction zone. The increase of roller force results in an increasing slope of the powder temperature profile. In addition, offline X-ray CT measurement results show the increase of density along the feeding to the compaction direction, which is compared with Johanson theory under different roller forces in the roller compaction process. Nanoparticles are promising drug delivery systems which are flexible for targeting specific tissues to reduce therapeutic doses and minimize side effects. Nanoparticles should be maintained with high stability and uniformity; however, aggregation is a major challenge which commonly impairs stability and efficacy of nanocarriers. In this study, we revisited the factors that influence the stability of chitosan (Protasan™ UP CL113) nanoparticles prepared with ionotropic gelation, widely recognized to be prone to aggregation, and proposed a model to overcome the negative influence of aggregation while testing in vitro efficacy. Decrease in pH due to cell proliferation, 37 °C cell culture temperature, serum in culture media, and incubation time were considered as factors causing chitosan nanoparticles' aggregation which deteriorates cell culture assay readouts, increases optical density values and leads to false-positive results. Size and stability studies were not sufficient to avoid misleading results in cell culture. The chitosan nanoparticle aggregation was almost inevitable under standard culture conditions; nevertheless, the removal of nanoparticles before aggregation but after an incubation period long enough for efficient cellular uptake was determined as a feasible and inexpensive method for testing the in vitro efficacy of polymeric nanoformulations. This approach was used with blank and gemcitabine-loaded chitosan nanoparticles on pancreatic cancer cells and proved to be useful for reliable cytotoxicity results. V.This work describes the synthesis of calcium zeolites (type A and X) and their use as drug carriers. This is the first example of using calcium zeolites as intelligent carriers that release drugs under the influence of body fluids. Both zeolites and zeolite/drug systems have been extensively characterized. It has been proven that calcium zeolites can be used as carriers of bisphosphonates (drugs against skeletal system diseases). This is due to the fact that phosphonate groups have strong interactions with calcium ions. The sorption of risedronate on zeolites in the sodium form was also carried out, but it was ineffective. The lack of effectiveness of sorption on the sodium zeolites confirms the theoretical assumptions presented in this work. Sorption occurred faster on type A zeolites while the release is faster for type X zeolites. Loading capacity (LC%) were at least 10% for both zeolite forms. The release may take over 100 h depending on the form of zeolite which will be used. The obtained materials have great potential as a drug carrier in enteric-coated tablets as well as an element of implants allowing for controlled drug release.

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