Cytotoxicity of Methotrexate Conjugated to Glycerol Phosphate Modified Superparamagnetic Iron Oxide Nanoparticles.

A systematic study was carried out to evaluate the uptake and cytotoxicity of methotrexate (MTX) conjugated to superparamagnetic iron oxide nanoparticles (SPIONs) modified with glycerol phosphate (Glyc) and phosphorylethanolamine (PEA), using MCF-7 cancer cell line as model. The ligand shell composition was controlled in such a way to get SPIONs with nine different surface functionalization and up to three co-conjugated ligands but the very iron oxide core, in order to test and compare uptake and cytotoxicity, and verify possible additive effects. Folic acid (FA), the non-toxic analogue of MTX, was also explored as ligand for SPIONs. Glyc was shown to enhance dramatically the cellular uptake despite the high negative zeta potentials, whereas PEA, FA and MTX was found to have a much lower effect on the cellular uptake. Also, a significant ten times lowering of IC50 was observed for the co-conjugated MTX in the SPION-Glyc/PEA/MTX as compared to the free drug, whereas the analogue SPION-Glyc/PEA/FA nanoparticles exhibited no significant cytotoxicity. In short, the conjugation of MTX to SPIONs enhanced dramatically its cytotoxicity and decreased the IC50 value against MCF-7 tumor cells as compared to the free drug, probably due to the enhanced uptake of SPIONs as a result of their surface modification with Glyc/PEA, demonstrating that SPION-Glyc/PEA is a good nanocarrier for co-conjugated methotrexate.

Porphyrin Derivative Nanoformulations for Therapy and Antiparasitic Agents.

Porphyrins and analogous macrocycles exhibit interesting photochemical, catalytic, and luminescence properties demonstrating high potential in the treatment of several diseases. Among them can be highlighted the possibility of application in photodynamic therapy and antimicrobial/antiparasitic PDT, for example, of malaria parasite. However, the low efficiency generally associated with their low solubility in water and bioavailability have precluded biomedical applications. Nanotechnology can provide efficient strategies to enhance bioavailability and incorporate targeted delivery properties to conventional pharmaceuticals, enhancing the effectiveness and reducing the toxicity, thus improving the adhesion to the treatment. In this way, those limitations can be overcome by using two main strategies: (1) Incorporation of hydrophilic substituents into the macrocycle ring while controlling the interaction with biological systems and (2) by including them in nanocarriers and delivery nanosystems. This review will focus on antiparasitic drugs based on porphyrin derivatives developed according to these two strategies, considering their vast and increasing applications befitting the multiple roles of these compounds in nature.

Beyond electrostatic interactions: Ligand shell modulated uptake of bis-conjugated iron oxide nanoparticles by cells.

The effect of the ligand shell on the cellular uptake efficiency was evaluated by a systematic study using fully dispersed 6 nm diameter superparamagnetic iron oxide nanoparticles (SPIONs), mono and bis-conjugated with glycerol phosphate (glyc), dopamine (dopa), 4,5-dihydroxy-1,3-benzenedisulfonic acid (tiron) and phosphorylethanolamine (pea). Negatively charged SPION-glyc was more efficiently incorporated than positively charged SPION-pea and SPION-dopa clearly evidencing that there are strong enough short-range interactions in addition to the long-range electrostatic interactions, as measured by the zeta potential, to reverse our expectation on cellular uptake. Those effects were pursued by correlating the nanoparticles incorporation efficiency as a function of the respective zeta potentials and the molar fractions of glyc and pea ligands co-conjugated on the SPION surface. The possibility of associating different ligands to modulate the physicochemical properties and biological events was demonstrated, showing promising perspectives for the development of multifunctional nanosystems for biomedical applications.

A reliable protocol for colorimetric determination of iron oxide nanoparticle uptake by cells.

Size, shape, and surface properties of superparamagnetic iron oxide nanoparticles (SPIONs) can influence their interaction with biological systems, particularly the incorporation by tumor cells and consequently the biological activity and efficiency in biomedical applications. Several strategies have been used to evaluate cellular uptake of SPIONs. While qualitative methods are generally based on microscopy techniques, quantitative assays are carried out by techniques such as inductively coupled plasma-mass spectrometry and flow cytometry. However, inexpensive colorimetric methods based on equipments commonly found in chemistry and biochemistry laboratories are preferred for routine measurements. Nevertheless, colorimetric assays must be used judiciously, particularly when nanoparticles are involved, since their interaction with biological constituents tends to lead to quite underestimated results. Thus, herein described is a colorimetric protocol using 2,2'-bipyridine as chromogenic ligand, where each step was optimized and validated by total reflection X-ray fluorescence spectroscopy, realizing a highly reproducible and reliable method for determination of iron content in cells incubated with SPIONs. The limit of blank and limit of detection were determined to be as low as 0.076 and 0.143 µg Fe/mL, using sample volumes as small as 190 µL and a number of cells as low as 2.0 × 105. Furthermore, three different types of surface-functionalized nanoparticles were incorporated in cells and evaluated through this protocol, enabling to monitor the additive effect of o-phosphorylethanolamine (PEA) and folic acid (FA) conjugation on iron oxide nanoparticles (SPION-PEA and SPION-PEA/FA), that enhanced the uptake by HeLa cells, respectively, by four and ten times when compared to SPIONs conjugated with nonbioactive molecules. Graphical abstract Colorimetric determination of superparamagnetic iron oxide nanoparticles (SPIONs) incorporated by cells.

Strategies for development of antimalarials based on encapsulated porphyrin derivatives.

Despite the efforts in controlling the parasite and infection, and the significant progress achieved in recent years in its treatment, malaria is still prevalent in many regions and out of control in others. The repertoire of alternatives to fight malaria is being expanded, not only by designing new drugs but also by developing improved drug delivery systems able to enhance the antimalarial efficiency of conventional and new drugs. Among the new drugs that have been investigated, several publications report the use of porphyrin derivatives as antimalarials but their efficiency is contradictory. The low activity of porphyrins seems to be associated with low dispersibility and bioavailability. In this respect, Nanotechnology can provide efficient solutions to enhance bioavailability and delivery of conventional and new antimalarials, in order to assure high enough efficiency levels to inactivate the parasite. Thus, in this review we highlight the use of drug delivery systems for conventional and new antimalarials and we propose the encapsulation of porphyrins as a promising alternative for development of anti-malarial formulations.

Encapsulation of metalloporphyrins improves their capacity to block the viability of the human malaria parasite Plasmodium falciparum.

Several synthetic metallated protoporphyrins (M-PPIX) were tested for their ability to block the cell cycle of the lethal human malaria parasite Plasmodium falciparum. After encapsulating the porphyrin derivatives in micro- and nanocapsules of marine atelocollagen, their effects on cultures of red blood cells infected (RBC) with P. falciparum were verified. RBCs infected with synchronized P. falciparum incubated for 48 h showed a toxic effect over a micromolar range. Strikingly, the IC50 of encapsulated metalloporphyrins reached nanomolar concentrations, where Zn-PPIX showed the best antimalarial effect, with an IC50=330 nM. This value is an 80-fold increase in the antimalarial activity compared to the antimalarial effect of non-encapsulated Zn-PPIX. These findings reveal that the incubation of P. falciparum infected-RBCs with 20 µM Zn-PPIX reduced the size of hemozoin crystal by 34%, whereas a 28% reduction was noticed with chloroquine, confirming the importance of heme detoxification pathway in drug therapy. FROM THE CLINICAL EDITOR: In this study, synthetic metalloporphyrins were tested as therapeutics that target Plasmodium falciparum. The IC50 of encapsulated metalloporphyrins was found to be in the nanomolar concentration range, with encapsulated Zn-PPIX showing an 80-fold increase in its antimalarial activity compared to the non-encapsulated form.

Nanobiosensors exploiting specific interactions between an enzyme and herbicides in atomic force spectroscopy.

The development of sensitive methodologies for detecting agrochemicals has become important in recent years due to the increasingly indiscriminate use of these substances. In this context, nanosensors based on atomic force microscopy (AFM) tips are useful because they provide higher sensitivity with operation at the nanometer scale. In this paper we exploit specific interactions between AFM tips functionalized with the enzyme acetolactate synthase (ALS) to detect the ALS-inhibitor herbicides metsulfuron-methyl and imazaquin. Using atomic force spectroscopy (AFS) we could measure the adhesion force between tip and substrate, which was considerably higher when the ALS-functionalized tip (nanobiosensor) was employed. The increase was approximately 250% and 160% for metsulfuron-methyl and imazaquin, respectively, in comparison to unfunctionalized probes. We estimated the specific enzyme-herbicide force by assuming that the measured force comprises an adhesion force according to the Johnson-Kendall-Roberts (JKR) model, the capillary force and the specific force. We show that the specific, biorecognition force plays a crucial role in the higher sensitivity of the nanobiosensor, thus opening the way for the design of similarly engineered tips for detecting herbicides and other analytes.

Control of cytolocalization and mechanism of cell death by encapsulation of a photosensitizer.

The most challenging and wanted development in photodynamic therapy is the control of photosensitizer (PS) cytolocalization and the mechanism of cell death. 5,10,15-triphenyl-20-(3-N-methylpyridinium-yl)porphyrin (3MMe) administered to HeLa cells as DMSO solution accumulates in the cytoplasmic membrane (CM) where it causes severe photodamage and cell necrosis. In contrast, when incorporated in marine atelocollagen/xantham gum polymeric nanocapsules, the PS is shuttled through CM allowing its gradual release and accumulation in mitochondria and lysosomes. Little photodamage was caused to cells in this case, but compelling evidences are presented showing that encapsulation changes the cytolocalization and shifts the cell death mechanism from necrosis to apoptosis. In conclusion, both of those challenges can be overcome by encapsulation of typical PSs such as 3MMe by using the new concept of photodynamic treatment with minimal cell damage by targeting specifically some key organelles. We are confident that these findings are important for the development of more efficient photosensitizers tailored to induce apoptosis while minimizing undesirable side effects such as over-inflammation.

Nanobiosensors based on chemically modified AFM probes: a useful tool for metsulfuron-methyl detection.

The use of agrochemicals has increased considerably in recent years, and consequently, there has been increased exposure of ecosystems and human populations to these highly toxic compounds. The study and development of methodologies to detect these substances with greater sensitivity has become extremely relevant. This article describes, for the first time, the use of atomic force spectroscopy (AFS) in the detection of enzyme-inhibiting herbicides. A nanobiosensor based on an atomic force microscopy (AFM) tip functionalised with the acetolactate synthase (ALS) enzyme was developed and characterised. The herbicide metsulfuron-methyl, an ALS inhibitor, was successfully detected through the acquisition of force curves using this biosensor. The adhesion force values were considerably higher when the biosensor was used. An increase of ~250% was achieved relative to the adhesion force using an unfunctionalised AFM tip. This considerable increase was the result of a specific interaction between the enzyme and the herbicide, which was primarily responsible for the efficiency of the nanobiosensor. These results indicate that this methodology is promising for the detection of herbicides, pesticides, and other environmental contaminants.

Resolution of isomeric multi-ruthenated porphyrins by travelling wave ion mobility mass spectrometry.

The ability of travelling wave ion mobility mass spectrometry (TWIM-MS) to resolve cationic meta/para and cis/trans isomers of mono-, di-, tri- and tetra-ruthenated supramolecular porphyrins was investigated. All meta isomers were found to be more compact than the para isomers and therefore mixtures of all isomeric pairs could be properly resolved with baseline or close to baseline peak-to-peak resolution (R(p-p)). Di-substituted cis/trans isomers were found, however, to present very similar drift times and could not be resolved. N(2) and CO(2) were tested as the drift gas, and similar α but considerably better values of R(p) and R(p-p) were always observed for CO(2).

A new micro/nanoencapsulated porphyrin formulation for PDT treatment.

The highly hydrophobic 5,10,15-triphenyl-20-(3-N-methylpyridinium-yl)porphyrin (3MMe) cationic species was synthesized, characterized and encapsulated in marine atelocollagen/xanthane gum microcapsules by the coacervation method. Further reduction in the capsule size, from several microns down to about 300-400 nm, was carried out successfully by ultrasonic processing in the presence of up to 1.6% Tween 20 surfactant, without affecting the distribution of 3MMe in the oily core. The resulting cream-like product exhibited enhanced photodynamic activity but negligible cytotoxicity towards HeLa cells. The polymeric micro/nanocapsule formulation was found to be about 4 times more phototoxic than the respective phosphatidylcholine lipidic emulsion, demonstrating high potentiality for photodynamic therapy applications.