Toxicity Evaluation for Safe Use of Nanomaterials: Recent Achievements and Technical Challenges

Recent developments in the field of nanotechnology involving the synthesis of novel nanomaterials (NM) have attracted the attention of numerous scientists owing to the possibility of degradative perturbations in human health. This Review evaluates previous investigations related to NM toxicity studies using biological models and describes the limitations that often prevent toxicologists from identifying whether NM pose a real hazard to human health. One major limitation to assess toxicity is the characterization of the NM prior to and after exposure to living cells or animals. The most relevant physicochemical characteristics of NM are: size, surface chemistry, crystallinity, morphology, solubility, aggregation tendency, homogeneity of dispersions, and turbidity. All of these properties need to be assessed in order to determine their contribution to toxicity. Due to the lack of appropriate methods to determine the physicochemical nature of nanoparticles in biological systems, the exact nature of NM toxicity is not fully described or understood at this time. This Review emphasizes the need for state‐of‐the‐art physicochemical characterization, the determination of appropriate exposure protocols and reliable methods for assessing NM internalization and their kinetics in living organisms. Once these issues are addressed, optimal experimental conditions could be established in order to identify if NM pose a threat to human health. Multidisciplinary research between materials scientists and life scientists should overcome these limitations in identifying the true hazards of NM.     

On One Leg: Trehalose Monoesters Activate Macrophages in a Mincle‐Dependent Manner

The C₂₂ and C₂₆ trehalose monoesters, each containing a single acyl chain, were synthesised in good overall yields and found to activate macrophages in a Mincle‐dependent manner. The activities of the monoesters paralleled those of their diester counterparts, and both mono‐ and diesters could activate the immune response in the absence of priming. This is the first time that trehalose monoesters have been found to activate macrophages, and these studies thus provide an important framework for the rational design of other Mincle agonists.     

Chemical Tools for Studying the Biological Function of Glycolipids

Glycolipids play an important role in many biological processes and to this end, synthetic chemists have developed a variety of new techniques and “chemical tools” that allow for the study of glycolipids in vitro and in vivo. The types of probes prepared include fluorescent, radio‐labelled, biotinylated and photoreactive ones, as well as others based on liposomes, microarrays and other supramolecular constructs—each of which offers its own advantages, as is discussed. A number of more specialised probes, such as metabolically engineered glycolipids and photopolymerisable glycolipids, have also been prepared in order to investigate various processes including substrate specificities and binding interactions. The purpose of this review is to present the key approaches that can be used for the development of glycolipid probes, organised according to application, and also to discuss the limitations of such strategies, which include the nontrivial task of ensuring that the probe does not adversely influence the biological activity of the parent compound. On the whole, it is exciting to see what can be achieved through the development of chemical probes as tools to study biological processes, and it is envisioned that the reader will be inspired by the large number of superb studies highlighted here and will be encouraged to undertake further work in this research area.     

Optimization of Focused Ultrasound Extraction (FUSE) and Supercritical Fluid Extraction (SFE) of Citrus Peel Volatile Oils and Antioxidants

In order to evaluate the use of citrus peel as a potential source of volatile oils and antioxidants in food industry, supercritical fluid extraction (SFE) and focused ultrasound extraction (FUSE) techniques have been thoroughly studied. Based on experimental designs and considering the extraction of monoterpenes among the volatile oils, the total phenol content, and the antioxidants, the most adequate extraction conditions have been defined for lemon and then applied to other citrus. The optimum SFE conditions for volatile oils and antioxidants were the following: pressure, 100 and 170 bar; temperature, 35 °C for both; flow, 1 mL/min in both cases; EtOH%, 0 and 40 %, respectively. FUSE extraction of the volatile oils was carried out with cyclohexane and the antioxidants with ethanol. The optimum instrumental conditions were roughly the same (extraction time 5 min, cycles 5 s^?1, and amplitude 30 % in both cases, and 10 and 15 mL, respectively, in the case of solvent volumes). Based on successive extractions, FUSE revealed a more efficient technique owing to the solvent features. Finally, a stability test of the content of aromas and antioxidant capacity was carried out and aromas were stable stored at 4 °C for 6 weeks and the antioxidant capacity, in the same conditions, for 13 weeks.     

The Uptake of Trehalose Glycolipids by Macrophages Is Independent of Mincle

Trehalose glycolipids play an important role in the pathogenesis of Mycobacterium tuberculosis and are used as adjuvants for vaccines; however, much still remains unanswered about the mechanisms through which these glycolipids exert their immunomodulatory potential. Recently, the macrophage‐inducible C‐type lectin Mincle was determined to be the receptor for trehalose glycolipids, yet the role played by Mincle in glycolipid uptake is unknown. Accordingly, we developed several fluorescent trehalose glycolipid reporter systems that can be used to study the uptake of soluble trehalose glycolipids and glycolipid‐coated particles by macrophages. Our studies revealed that, although Mincle is essential for the activation of macrophages by trehalose glycolipids, the receptor does not play a role in the uptake of these glycolipids or of glycolipid‐coated particles.     

Synthesis and Biological Activity of the Lipoteichoic Acid Anchor from Streptococcus sp. DSM 8747

In this study, the role of lipoteichoic acid (LTA) anchors in the activation of the innate immune response was investigated through the chemical synthesis of a series of LTA derivatives and the determination of their ability to induce NO production in bone marrow‐derived macrophages (BMM). To this end, an efficient synthesis of the sn‐3‐O‐(α‐D ‐galactofuranosyl)‐1,2‐di‐O‐acylglycerol LTA core was developed, which was then used as a key structure to produce both phosphate and glycerylphosphate‐funtionalised LTA anchors, as well as galactofuranosyldiglycerides with different fatty acid chain lengths. With a series of LTA anchors in hand, we then determined the effect of these glycolipids on the innate immune response by exploring their capacity to activate macrophages. Here, we report that several of the LTA‐derivatives were able to induce NO production by BMMs. In general, the unnatural (sn‐1) core glycolipid anchors showed lower levels of activity than the corresponding natural (sn‐3) analogues, and the activity of the glycolipids also appears to be dependent on the length of lipid present, with an optimum lipid length of C20 for the sn‐3 derivatives. Interestingly, a triacylated anchor and the 6‐O‐phosphorylated anchor, showed only modest activity, while the 6‐O‐glycerophosphorylated derivative was unable to induce NO production. Taken as a whole, our results highlight the subtle effects that glycolipid length can have on the ability to activate BMMs.     

Technique for high axial shielding factor performance of large-scale, thin, open-ended, cylindrical Metglas magnetic shields

Metglas 2705M is a low-cost commercially available, high-permeability cobalt-based magnetic alloy, provided as a 5.08-cm wide and 20.3-μm thick ribbon foil. We present an optimized construction technique for single-shell, large-scale (human-size), thin, open-ended cylindrical Metglas magnetic shields. The measured dc axial and transverse magnetic shielding factors of our 0.61-m diameter and 1.83-m long shields in the Earth's magnetic field were 267 and 1500, for material thicknesses of only 122 μm (i.e., 6 foil layers). The axial shielding performance of our single-shell Metglas magnetic shields, obtained without the use of magnetic shaking techniques, is comparable to the performance of significantly thicker, multiple-shell, open-ended Metglas magnetic shields in comparable-magnitude, low-frequency applied external fields reported previously in the literature.     

Species-specific activity of glycolipid ligands for invariant NKT cells

The immunomodulatory glycolipid α-galactosylceramide (α-GalCer) binds to CD1d and exhibits potent activity as a ligand for invariant CD1d-restricted natural killer-like T cells (iNKT cells). Structural analogues of α-GalCer have been synthesised to determine which components are required for CD1d presentation and iNKT cell activation, however, to date the importance of the phytosphingosine 4-hydroxyl for iNKT cell activation has been disputed. To clarify this, we synthesised two 4-deoxy α-GalCer analogues (sphinganine and sphingosine) and investigated their ability to activate murine and human iNKT cells. Analysis revealed that the analogues possessed comparable activity to α-GalCer in stimulating murine iNKT cells, but were severely compromised in their ability to stimulate human iNKT cells. Here we determined that species-specific glycolipid activity was due to a lack of recognition of the analogues by the T-cell receptors on human iNKT cells rather than insufficient presentation of the analogues on human CD1d molecules. From these results we suggest that glycolipids developed for potent iNKT cell activity in humans should contain a phytosphingosine base.     

Pharmacokinetic and pharmacodynamic models of the antistaphylococcal effects of meropenem and cloxacillin in vitro and in experimental infection

The efficacies of meropenem (MPM) and cloxacillin (CLC) against two Staphylococcus aureus strains were established in vitro. A pharmacodynamic model equation, based on the concept that the killing rate depends on concentration and time, was fitted to the numbers of CFU. The parameters of the equation are maximum killing rate, time point of maximum killing, and 50% effective concentration (EC50). The EC50s for the two strains were 0.047 and 0.040 mg/liter, respectively, for MPM and 0.105 and 0.121 mg/liter, respectively, for CLC. Calculated values of the parameters were used to predict the numbers of CFU at exponentially decreasing concentrations in vitro as well as in an experimental infection model. The prediction for in vitro conditions gave a satisfactory fit (R2, between 0.862 and 0.894). In vivo the numbers were predicted with the assumption that killing rate in vivo is proportional to that in vitro (R2, between 0.731 and 0.973). The proportionality factor ranged between 0.23 and 0.42; this variation was due mainly to covariation with growth rates in control animals, without other significant differences between antibiotics or strains.