Hydrophobic and hydrophilic drug loading capacity of micro diatom frustule from diatomite

The aim of this work was to strengthen the evidence of using micro diatom frustule as a promising candidate for drug loading materials for both hydrophobic and hydrophilic drug models. The morphological, surface elemental composition of diatomite powder, a raw source of micro diatom frustules and purified diatomite to collect micro diatom frustule were investigated. Scanning electron microscope (SEM) and X-ray photoelectron spectroscopy (XPS) confirmed again the porous silica structure of micro diatom structure as well as validated a necessity of raw diatomite purification before using. UV- vis was used to measure drug loading content of untreated and treated surface of micro diatom frustule with maximum loading for hydrophobic and hydrophilic drugs after 24 hours were at 5.48 ± 0.42% and 5.70 ± 0.34, respectively. Moreover, we also proved that the ability of drug adsorption on materials surface by the reduction of specific surface area and pore size of micro diatom frustule after loading using a (Brunauer–Emmett–Teller) BET method. Besides, the hydrophobic loading capacity of materials was affected by surface modification. Based on the results, micro diatom frustule showed a potential for a drug delivery system.

Imaging-Guided Delivery of a Hydrophilic Drug to Eukaryotic Cells Based on Its Hydrophobic Ion Pairing with Poly(hexamethylene guanidine) in a Maleated Chitosan Carrier

Imaging-guided delivery is developed for hydrophobic drugs, and to a much lesser extent, hydrophilic ones. In this work we have designed a novel strategy for real-time monitoring of hydrophilic drug delivery. Traditionally, the drug and the dye are covalently attached to a nanocarrier or are electrostatically adsorbed. Recently, we found an efficient way to bind the drug by ion-paring with an appropriate counter-ion to form the aggregate that embeds a hydrophobic dye with a considerable fluorescence enhancement. We synthesized a series of carbocyanine dyes of hydrophobicity sufficient for solubilization in hydrophobic ion pairs, which restores their emission in the near-infrared (NIR) region upon the formation of the ternary aggregates. To avoid using toxic surfactants, we applied an amphiphilic polymer-oligomer poly(hexamethylene guanidine) (PHMG) as a counter-ion. Сeftriaxone was used as a model hydrophilic drug ensuring the highest fluorescent signal. The so-formed drug–counter-ion–dye aggregates were encapsulated into a cross-linked maleated chitosan carrier. Confocal laser scanning microscopy (CLSM) studies have demonstrated internalization of the encapsulated model drug by breast adenocarcinoma cells at 40 min after treatment. These results suggest the potential application of hydrophobic ion pairs containing an NIR dye in imaging-guided delivery of hydrophilic compounds.

Ultrasound-Mediated Drug Delivery With a Clinical Ultrasound System: In Vitro Evaluation

Chemotherapy efficacy is often reduced by insufficient drug uptake in tumor cells. The combination of ultrasound and microbubbles (USMB) has been shown to improve drug delivery and to enhance the efficacy of several drugs in vitro and in vivo, through effects collectively known as sonopermeation. However, clinical translation of USMB therapy is hampered by the large variety of (non-clinical) US set-ups and US parameters that are used in these studies, which are not easily translated to clinical practice. In order to facilitate clinical translation, the aim of this study was to prove that USMB therapy using a clinical ultrasound system (Philips iU22) in combination with clinically approved microbubbles (SonoVue) leads to efficient in vitro sonopermeation. To this end, we measured the efficacy of USMB therapy for different US probes (S5-1, C5-1 and C9-4) and US parameters in FaDu cells. The US probe with the lowest central frequency (i.e. 1.6 MHz for S5-1) showed the highest USMB-induced intracellular uptake of the fluorescent dye SYTOX™ Green (SG). These SG uptake levels were comparable to or even higher than those obtained with a custom-built US system with optimized US parameters. Moreover, USMB therapy with both the clinical and the custom-built US system increased the cytotoxicity of the hydrophilic drug bleomycin. Our results demonstrate that a clinical US system can be used to perform USMB therapy as efficiently as a single-element transducer set-up with optimized US parameters. Therefore, future trials could be based on these clinical US systems, including validated US parameters, in order to accelerate successful translation of USMB therapy.

Rituximab-drug Conjugate Incorporating Auristatin E via A Quaternary Ammonium Linker Inducing Potent Antitumor Activity Against Non-Hodgkin’s B-cells

Background: Rituximab represents a drug used for standard Non-Hodgkin’s B-cell lymphoma therapy; however, it displays limited clinical efficacy. Antibody-drug conjugate (ADC) is one of the potential strategies to increase the antitumor activity of an antibody, with improved cytotoxicity directly resulting from the delivery of a molecular warhead. Currently, the warhead monomethyl auristatin E (MMAE) has been widely applied in the study of ADCs, conjugated to a carbamate-based linker (MC-VC-PABC). However, the hydrophobic drug-linker (MC-VC-PABC-MMAE) may lead to ADC aggregation, ultimately resulting in decreased activity. Objective: In this study, we developed a hydrophilic drug-linker MC-VC-PABQ-AE linked to rituximab.. If the replacement of the tertiary amine in AE for a secondary amine in MMAE represents a characteristic modification, the change of antitumor activity of two corresponding anti-CD20 ADC is unknown, requiring further verification. Method: The structural elucidation of MC-VC-PAB-AE was displayed by high-resolution mass spectra. The average drug antibody ratio (DAR) of rituximab-VC-AE/MMAE ADCs was performed by HIC-HPLC. The cell cycle arrest analysis of two ADCs was detected by flow cytometry, and the antitumor activity of two ADCs was evaluated in vitro against Ramos and Daudi cells. Results: The average drug antibody ratio (DAR) of two ADCs was approximately 4.0. The activities of rituximab-VC-AE could be increased in CD20 positive B-lymphoma cell lines, most notably due to the higher cell viability inhibitory rates and apoptosis rates compared to rituximab-VC-MMAE. Conclusions: A hydrophilicity linker of ADC was developed and studied. Rituximab-VC-AE may potentially be used against CD20-positive cells, and the therapeutic efficacy and safety bring about further investigations.

Liquid Lipids Act as Polymorphic Modifiers of Tristearin-Based Formulations Produced by Melting Technologies

Despite the growing interest in lipid-based formulations, their polymorphism is still a challenge in the pharmaceutical industry. Understanding and controlling the polymorphic behavior of lipids is a key element for achieving the quality and preventing stability issues. This study aims to evaluate the impact of different oral-approved liquid lipids (LL) on the polymorphism, phase transitions and structure of solid lipid-based formulations and explore their influence on drug release. The LL investigated were isopropyl myristate, ethyl oleate, oleic acid, medium chain trigycerides, vitamin E acetate, glyceryl monooleate, lecithin and sorbitane monooleate. Spray-congealing was selected as an example of a melting-based solvent-free manufacturing method to produce microparticles (MPs) of tristearin (Dynasan®118). During the production process, tristearin MPs crystallized in the metastable α-form. Stability studied evidenced a slow phase transition to the stable β-polymorph overtime, with the presence of the α-form still detected after 60 days of storage at 25 °C. The addition of 10% w/w of LL promoted the transition of tristearin from the α-form to the stable β-form with a kinetic varying from few minutes to days, depending on the specific LL. The combination of various techniques (DSC, X-ray diffraction analysis, Hot-stage polarized light microscopy, SEM) showed that the addition of LL significantly modified the crystal structure of tristearin-based formulations at different length scales. Both the polymorphic form and the LL addition had a strong influence on the release behavior of a model hydrophilic drug (caffeine). Overall, the addition of LL can be considered an interesting approach to control triglyceride crystallization in the β-form. From the industrial viewpoint, this approach might be advantageous as any polymorphic change will be complete before storage, hence enabling the production of stable lipid formulations.

An Emerging Era for Targeted Drug Delivery: Nanosponges

Many forms of Pharmaceutical product like nanosponge, nanoemulsion, nano-micelles, and nanosomes have been developed using nanotechnology. The size of Nanosponges is like that of a virus. They are very tiny in size and can permeate through the skin easily. Nanosponges can be distributed throughout the body until they reach their specific target area, where they adhere to the surface and the drug is released in a controlled manner, rather than circulating throughout the body. Nanosponge is a promising strategy to overcome problems associated with formulations such as poor bioavailability, drug toxicity, drug degradation, drug solubility and site specificity of drug. Both lipophillic and hydrophilic drug are incorporated in nanosponge. They can also act as biocatalysts and carrier for enzymes, antibodies, protein and vaccines. The use of a biodegradable polymer can help to maintain a constant drug level by allowing the drug to be released in a controlled way. Technologies employed in nanosponge formulations have been widely studied for drug delivery by topical, oral as well as parenteral administration. Improvement of solubility of poorly water soluble drug is another significant characteristic of Nanosponges. The primary goal of this review article is to provide a basic understanding of nanosponges, including their preparation process, advantages and disadvantages, as well as methods of evaluation and applications.