Recent progress of polymeric nanogels for gene delivery

With its nearly unrestricted possibilities, gene therapy attracts more and more significance in modern-day research. The only issue still seeming to hold back its clinical success is the actual effective delivery of genetic material. Nucleic acids are in general challenging to administer to their intracellular targets because of their unfavorable pharmaceutical characteristics. Polymeric nanogels present a promising delivery platform for oligonucleotide-based therapies, as the growing number of reports deliberated in this review represents. Within the scope of this article, recent progress in the use of nanogels as gene delivery vectors is summarized and different examples of modified, stimuli-responsive, targeted, and codelivering nanogels are discussed in detail. Furthermore, major aspects of successful gene delivery are addressed and critically debated in regard to nanogels, giving insights into what progress has been made and which key issues still need to be further approached.     

The effect of structure on improvement of the PNA Young modulus: A study of steered molecular dynamics

Prefoldin is a molecular chaperone and acts as a nano-actuator in cargo carriage and drug delivery for disease treatment. Investigating the mechanical properties of nano-actuator helps predict its behavior and measure its performance under various environmental conditions, like external forces that are applied. Accordingly, this paper investigates the elastic properties of the Prefoldin nano-actuator (PNA), specifically its Young modulus and the structural changes on a microscopic scale. For this purpose, three structurally different PNAs obtained from Protein Data Bank (PDB) and previous studies of our research team have been used. The selected three-tentacles Prefoldin are analyzed via the series of steered molecular dynamics simulations (SMD) based on the theory of Two Springs in Series. The simulation is applied in the velocity of 0.1, 0.05, and 0.01. Due to differences in the structure of the Prefoldin, PNAs exhibited different behaviours at various pull rates. Also, the analysis showed different values of Young's modulus for the PNA tentacles in the interval of (2.5–4 GPa). Understanding the mechanical properties of a Prefoldin nano actuator allows for a closer examination of its application in transportation the pathogenic cargos and intelligent drug delivery.     

Controlled drug delivery systems based on calixarenes

Recent advances on calixarene-based drug delivery systems in the form of inclusion complexes, amphiphilic self-assembly nanocarriers including micelles, hydrogels, vesicles and liposomes, and supramolecular nanovalves on mesoporous silicas, were reviewed and discussed.     

In vitro and in vivo evaluation of silk fibroin-hardystonite-gentamicin nanofibrous scaffold for tissue engineering applications

Designing advanced biomaterials with regenerative and drug delivering functionalities remains a challenge in the field of tissue engineering. In this paper we present the design, development, and a use case of an electrospun nano-biocomposite scaffold composed of silk fibroin (SF), hardystonite (HT), and gentamicin (GEN). The fabricated SF nanofiber scaffolds provide mechanical support while HT acts as a bioactive and drug carrier, on which GEN is loaded as an antibacterial agent. Antibacterial zone of inhibition (ZOI) results indicate that the inclusion of 3–6 wt% GEN significantly improves the antibacterial performance of the scaffolds against Gram-negative Escherichia coli (E. coli) and Gram-positive Staphylococcus aureus (S. aureus) bacteria, with an initial burst release of 10–20% and 72–85% total release over 7 days. The release rate of stimulatory silicon ions from SF-HT scaffolds reached 94.53±5 ppm after 7 days. Cell studies using osteoblasts show that the addition of HT significantly improved the cytocompatibility of the scaffolds. Angiogenesis, in vivo biocompatibility, tissue vascularization, and translatability of the scaffolds were studied via subcutaneous implantation in a rodent model over 4-weeks. When implanted subcutaneously, the GEN-loaded scaffold promoted angiogenesis and collagen formation, which suggests that the scaffold may be highly beneficial for further bone tissue engineering applications.     

Effect of metal atoms on the electronic properties of metal oxide nanoclusters for use in drug delivery applications: a density functional theory study

To improve drug selectivity toward target cells, one interesting technique for drug delivery is to use nanostructured materials. Recent studies revealed that the fullerene-like nanoclusters can pass through cell walls and transport and release drugs in the target site. In this study, the reactivity, and electronic sensitivity of the Be12O12, Mg12O12, and Zn12O12 nanoclusters were investigated toward hydroxyurea (HU) anticancer drug using density functional theory calculations at gas phase and aqueous solution. Our results show that the electronic properties of Mg12O12 and Zn12O12 nanoclusters are significantly sensitive to the presence of HU and the nanoclusters may be a promising candidate for adsorption of this drug. The results show that all complexes are energetically favourable, especially in the aqueous phase. Also, our ultraviolet–visible results show that the electronic spectra of HU/(MO)12 complexes exhibit a blue shift toward lower wavelengths (higher energies). To go further and gain insight into the binding features of considered (MO)12 nanoclusters with HU drug, the Atoms in Molecules analysis was performed. Our results determine the electrostatic features of the HU/Mg12O12 and HU/Zn12O12 bonding. Consequently, the results demonstrated that the Mg12O12 and Zn12O12 nanoclusters could be used as potential carriers for the delivery of HU drug.     

Automated on-line liquid–liquid extraction system for temporal mass spectrometric analysis of dynamic samples

Most real samples cannot directly be infused to mass spectrometers because they could contaminate delicate parts of ion source and guides, or cause ion suppression. Conventional sample preparation procedures limit temporal resolution of analysis. We have developed an automated liquid–liquid extraction system that enables unsupervised repetitive treatment of dynamic samples and instantaneous analysis by mass spectrometry (MS). It incorporates inexpensive open-source microcontroller boards (Arduino and Netduino) to guide the extraction and analysis process. Duration of every extraction cycle is 17 min. The system enables monitoring of dynamic processes over many hours. The extracts are automatically transferred to the ion source incorporating a Venturi pump. Operation of the device has been characterized (repeatability, RSD = 15%, n = 20; concentration range for ibuprofen, 0.053–2.000 mM; LOD for ibuprofen, ∼0.005 mM; including extraction and detection). To exemplify its usefulness in real-world applications, we implemented this device in chemical profiling of pharmaceutical formulation dissolution process. Temporal dissolution profiles of commercial ibuprofen and acetaminophen tablets were recorded during 10 h. The extraction-MS datasets were fitted with exponential functions to characterize the rates of release of the main and auxiliary ingredients (e.g. ibuprofen, k = 0.43 ± 0.01 h⁻¹). The electronic control unit of this system interacts with the operator via touch screen, internet, voice, and short text messages sent to the mobile phone, which is helpful when launching long-term (e.g. overnight) measurements. Due to these interactive features, the platform brings the concept of the Internet-of-Things (IoT) to the chemistry laboratory environment.     

Molecular dynamics simulation study of gold nanosheet as drug delivery vehicles for anti-HIV-1 aptamers

The adsorption process of three aptamers with gold nanosheet (GNS) as a drug carrier has been investigated with the help of molecular dynamics simulations. The sequencing of the considered aptamers are as (CUUCAUUGUAACUUCUCAUAAUUUCCCGAGGCUUUUACUUUCGGGGUCCU) and (CCGGGUCGUCCCCUACGGGGACUAAAGACUGUGUCCAACCGCCCUCGCCU) for AP1 and AP2, respectively. AP3 is a muted version of AP1 in which nucleotide positions 4, 6, 18, 28 and 39 have C4A, U6G, A18G, G28A, and U39C mutations. At positions 24, and 40, a deletion mutation is seen to eliminate U24 and U40 bases. These aptamers are inhibitors for HIV-1 protease and can be candidates as potential pharmaceutics for treatment of AIDS in the future. The interactions between considered aptamers and GNS have been analyzed in detail with help of structural and energetic properties. These analyses showed that all three aptamers could well adsorb on GNS. Overall, the final results show that the adsorption of AP2 on the GNS is more favorable than other considered ones and consequently GNS can be considered as a device in order to immobilize these aptamers.     

Synthesis of ortho-substituted nitroaromatics via improved Negishi coupling conditions

We describe modified Negishi coupling conditions that allow improved access to ortho-nitrophenylalanine derivatives. These useful amino acid intermediates can be further elaborated into biologically active lactams and cyclic hydroxamic acid targets.     

药物包载对两亲嵌段共聚物胶束形态的影响

以聚(ε-己内酯-b-L-丙交酯)/聚乙二醇单甲醚(P(CL-b-LLA)-b-mPEG)和聚(ε-己内酯-b-D,L-丙交酯)/聚乙二醇单甲醚(P(CL-b-DLLA)-b-mPEG)两种两亲嵌段共聚物为载体,选择了物理状态完全不同、而疏水性相近的吲哚美辛和维生素E为模型药物,研究了药物包载对高分子胶束形态的影响.发现两种药物在高分子胶束内部的增溶均会导致胶束形态发生显著改变,变化行为与胶束内核的结晶性和药物疏水性有关.另外,还研究了两种嵌段共聚物的载药性能,发现非结晶性疏水内核共聚物的药物包载率明显大于可结晶疏水内核的共聚物.