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Virtual worlds (VWs) present a viable, low-cost delivery mechanism for telehealth services. Although preliminary reports support the effectiveness of VWs in terms of health metrics, few studies have examined the perceived benefits and learning potential for military service members and veterans. Trust is integral to any interaction and may be even more important, and problematic to establish, during virtual interactions than in-person (IP) communications. The purpose of this study was to compare active duty and veteran U.S. Military service members' (n = 92) self-reported trust, class satisfaction, and didactic learning after completing either an 8-week training course in mindfulness-based stress reduction (MBSR) delivered IP or an 8-week mindfulness meditation class based on MBSR via the VW of Second Life. Results showed that learning performance was not significantly different between the IP and VW groups (p > 0.05). Although overall trust was high for both groups, participants in the IP group reported greater trust and class satisfaction compared with the VW group (p  less then  0.05). Trust, satisfaction, and learning were significantly correlated with one another, and trust in the instructor significantly predicted trust-in-classmates, trust-in-self, and class satisfaction for both groups (p  less then  0.05). In this study, IP group training was superior to VW training in terms of self-reported greater trust in the instructor, classmates, and self, and higher satisfaction with the training. Go 6983 Trust in the instructor is particularly important for group training, whether IP or in a VW. This study reiterates the arduous task of establishing trust in a VW setting and suggests that creating trust between the instructor and participants is high priority as a leading objective for VW communications. Suggestions for building trust are tight collaboration and clear communication, along with supporting and advocating for one another.We used all-atom replica-exchange umbrella sampling molecular dynamics simulations to investigate the partitioning of the charged tetrapeptide KLVF and its neutral apolar counterpart VVIA into the blood-brain barrier (BBB)-mimetic bilayer. Our findings allowed us to reconstruct the partitioning mechanism for these two Aβ peptide fragments. Despite dissimilar sequences, their permeation shares significant common features. Computations of free energies and permeabilities show that partitioning of both peptides is highly unfavorable, ruling out passive transport. The peptides experience multiple rotational transitions within the bilayer and typically cause considerable lipid disorder and bilayer thinning. Near the bilayer midplane, they lose almost entirely their solvation shell and the interactions with the lipid headgroups. The peptides cause complex reorganization within the proximal bilayer region. Upon insertion, they induce striking cholesterol influx reversed by its depletion and the influx of DMPC when the peptides reach the midplane. The differences in partitioning mechanisms are due to the much higher polarity of KLVF peptide, the permeation of which is more unfavorable and which exclusively assumes vertical orientations within the bilayer. In contrast, VVIA positions itself flat between the leaflets, causing minor disorder and even thickening of the BBB-mimetic bilayer. Due to the high density of the cholesterol-rich BBB bilayer, the unfavorable work associated with the peptide insertion provides a significant, but not dominant, contribution to the partition free energy, which is still governed by dehydration and loss of peptide-headgroup interactions. Comparison with experiments indicates that KLVF and VVIA permeation is similar to that of proline tetrapeptide, mannitol, or cimetidine, all of which exhibit no passive transport.The combination of Flash NanoPrecipitation and hydrophobic ion pairing (HIP) is a valuable approach for generating nanocarrier formulations of ionic water-soluble drugs with controllable release properties dictated by liquid crystalline structuring of the ion pairs. However, there are few examples of this in practice in the literature. This work aims to decipher the influence of the nature of the hydrophobic counterion used in HIP and its consequent impact on liquid crystalline structuring and drug release. The hypothesis of this study was that hydrophobic counterions with different head and tail groups used for FNP with HIP would give rise to different liquid crystalline structures, which in turn would result in different drug release behavior. A cationic, water-soluble antibiotic, polymixin B, was complexed with eight different hydrophobic counterions with varying head and tail groups and encapsulated into nanocarriers 100-400 nm in size prepared using FNP. Sixteen formulations were assessed for internal ststanding of the types of controlled release formulations that are possible using FNP with HIP.In this study, various structurally similar aliphatic dicarboxylic acids, namely, succinic acid, glutaric acid, adipic acid, and pimelic acid, were employed as coformers to obtain phase pure cocrystals with berberine chloride (BCl) by a slow solvent evaporation method. The structures of the four novel salt-cocrystals of BCl were determined by single crystal X-ray diffraction analysis and their solid-state properties were characterized. Compared with BCl·2H2O, all the cocrystals showed a higher melting point, improved powder dissolution and intrinsic dissolution rate (IDR), and lower hygroscopicity. It is noteworthy that the melting points and IDRs of these cocrystals exhibit an odd-even alternation with the carbon chain length of the acids.The goal of this study was molecular modeling of cyclodextrin (CD) and carotenoid complex formation. Distinction was made between complexes resulting from interactions between carotenoids and either molecularly dispersed CDs or solid crystalline CDs, considering that both cases can occur depending on the complex formation process pathways. First, the formation of complexes from dispersed CD molecules was investigated considering five different CDs (αCD, βCD, methyl-βCD, hydroxypropyl-βCD, and γCD) and lutein, as a model carotenoid molecule. The interactions involved and the stability of the different complexes formed were evaluated according to the CD size and steric hindrance. Second, the formation of complexes between four different crystalline CDs (βCD with three different water contents and methyl-βCD) and three carotenoid molecules (lutein, lycopene, and β-carotene) was studied. The docking/adsorption of the carotenoid molecules was modeled on the different faces of the CD crystals. The findings highlight that all the CD faces, and thus their growth rates, were equally impacted by the adsorption of the carotenoids.