Quantitative biokinetics of titanium dioxide nanoparticles after intratracheal instillation in rats: Part 3

The biokinetics of a size-selected fraction (70?nm median size) of commercially available and ⁴⁸V-radiolabeled [⁴⁸V]TiO₂ nanoparticles has been investigated in healthy adult female Wistar-Kyoto rats at retention time-points of 1?h, 4?h, 24?h, 7?d and 28?d after intratracheal instillation of a single dose of an aqueous [⁴⁸V]TiO₂-nanoparticle suspension. A completely balanced quantitative biodistribution in all organs and tissues was obtained by applying typical [⁴⁸V]TiO₂-nanoparticle doses in the range of 40–240?μg·kg^?1 bodyweight and making use of the high sensitivity of the radiotracer technique. The [⁴⁸V]TiO₂-nanoparticle content was corrected for residual blood retained in organs and tissues after exsanguination and for ⁴⁸V-ions not bound to TiO₂-nanoparticles. About 4% of the initial peripheral lung dose passed through the air-blood-barrier after 1?h and were retained mainly in the carcass (4%); 0.3% after 28?d. Highest organ fractions of [⁴⁸V]TiO₂-nanoparticles present in liver and kidneys remained constant (0.03%). [⁴⁸V]TiO₂-nanoparticles which entered across the gut epithelium following fast and long-term clearance from the lungs via larynx increased from 5 to 20% of all translocated/absorbed [⁴⁸V]TiO₂-nanoparticles. This contribution may account for 1/5 of the nanoparticle retention in some organs. After normalizing the fractions of retained [⁴⁸V]TiO₂-nanoparticles to the fraction that reached systemic circulation, the biodistribution was compared with the biodistributions determined after IV-injection (Part 1) and gavage (GAV) (Part 2). The biokinetics patterns after IT-instillation and GAV were similar but both were distinctly different from the pattern after intravenous injection disproving the latter to be a suitable surrogate of the former applications. Considering that chronic occupational inhalation of relatively biopersistent TiO₂-particles (including nanoparticles) and accumulation in secondary organs may pose long-term health risks, this issue should be scrutinized more comprehensively.     

Microradiopharmaceutical for Metastatic Melanoma

Pharmaceutical Research - The purpose of this article was to develop, characterize and test (in vivo) dacarbazine microparticles that may be labeled with 99mTc and Ra-223 for both use: diagnostic...     

Cyclotron production of 64Cu by deuteron irradiation of 64Zn.

The short-lived (12.7h half-life) (64)Cu radioisotope is both a beta(+) and a beta(-) emitter. This property makes (64)Cu a promising candidate for novel medical applications, since it can be used simultaneously for therapeutic application of radiolabelled biomolecules and for diagnosis with PET. Following previous work on (64)Cu production by deuteron irradiation of natural zinc, we report here the production of this radioisotope by deuteron irradiation of enriched (64)Zn. In addition, yields of other radioisotopes such as (61)Cu, (67)Cu, (65)Zn, (69m)Zn, (66)Ga and (67)Ga, which were co-produced in this process, were also measured. The evaporation code ALICE-91 and the transport code SRIM 2003 were used to determine the excitation functions and the stopping power, respectively. All the nuclear reactions yielding the above-mentioned radioisotopes were taken into account in the calculations both for the natural and enriched Zn targets. The experimental and calculated yields were shown to be in reasonable agreement. The work was carried out at the Scanditronix MC-40 Cyclotron of the Institute for Health and Consumer Protection of the Joint Research Centre of the European Commission (Ispra site, Italy). The irradiations were carried out with 19.5 MeV deuterons, the maximum deuteron energy obtainable with the MC-40 cyclotron.     

Study of 223Ra uptake mechanism on hydroxyapatite and titanium dioxide nanoparticles as a function of pH

The mechanism of ²²³Ra uptake on hydroxyapatite and titanium dioxide nanoparticles was studied as a function of pH. Both materials are widely used in food industry and medicine. They offer properties suitable for labelling with medicinal radionuclides, particularly for targeted radionuclide therapy. The selected isotope, ²²³Ra, is an alpha emitter widely used in targeted alpha particle therapy due to high-dose delivery in very small tissue volume, nevertheless the results are applicable for any radium isotope including ²²⁶Ra. The study was performed in the pH range 4.5 to 12 for hydroxyapatite nanoparticles and 2 to 12 for titanium dioxide nanoparticles in Britton–Robinson buffer solution. Both nanomaterials at pH 6 and higher showed that over 95% of the radium has been sorbed. According to the applied chemical equilibrium model, the most important species playing a role in sorption on the edge-sites were RaCO₃, RaPO₄⁻, RaHPO₄ and Ra(Ac⁻)₂, and Ra²⁺ and RaH₂PO₄⁺ on layer-sites. All experiments were conducted under free air conditions and no negative impact of CO₂ was found. The surface complexation model was found suitable for describing radium uptake by the studied hydroxyapatite and titanium dioxide nanomaterials.

The mechanism of ²²³Ra uptake on hydroxyapatite and titanium dioxide nanoparticles was studied as a function of pH.     

Astatination of nanoparticles containing silver as possible carriers of 211At.

The alpha emitter 211At is a prospective radionuclide for the therapy of smaller tumours and metastases. However, the chemical properties of 211At together with the fact that it is available only in trace amounts, makes the labelling of prospective astatine carriers rather complicated. In this context we have studied a new class of possible astatine carriers--nanoparticle systems, which tend to concentrate themselves in some types of tumours by means of the EPR effect. Additionally, such nanoparticles have the advantage that they may be chemically modified by the attachment of a tumour-seeking agent, and also directly applied to the target site. In order to reach high labelling yields, and in order to protect the nanoparticles from rapid degradation by the immune system, silver-containing particles covalently coated by poly(ethylene oxide) were developed and tested. The effect of the different reducing and oxidizing agents on the labelling yield was also determined. It was found that labelling yields were almost quantitative and well reproducible under reducing conditions, while under oxidizing conditions they dropped to ca. 50%. In the absence of any reducing or oxidizing agent, the labelling yields were randomly distributed between a range of 50% and 97%. The labelled nanoparticles were stable even in a large surplus of competing chloride ions.     

Thermoresponsive polymers as promising new materials for local radiotherapy.

We describe a novel thermoresponsive polymeric drug delivery system based on poly(N-isopropylacrylamide) with isotopically labellable end groups [l-tyrosinamide or diethylenetriaminepentaacetic acid (DTPA)] designed for local radiotherapy. The polymers are readily soluble in isotonic aqueous sodium chloride at room temperature and the phase separation is complete at body temperature as proved by DSC measurements. Sufficent binding capacity for radionuclides and chemical stability are demonstrated on 125I and 90Y-labelled polymers.     

Quantitative biokinetics of titanium dioxide nanoparticles after intravenous injection in rats: Part 1

Submicrometer TiO₂ particles, including nanoparticulate fractions, are used in an increasing variety of consumer products, as food additives and also drug delivery applications are envisaged. Beyond exposure of occupational groups, this entails an exposure risk to the public. However, nanoparticle translocation from the organ of intake and potential accumulation in secondary organs are poorly understood and in many investigations excessive doses are applied. The present study investigates the biokinetics and clearance of a low single dose (typically 40–400?μg/kg BW) of ⁴⁸V-radiolabeled, pure TiO₂ anatase nanoparticles ([⁴⁸V]TiO₂NP) with a median aggregate/agglomerate size of 70?nm in aqueous suspension after intravenous (IV) injection into female Wistar rats. Biokinetics and clearance were followed from one-hour to 4-weeks. The use of radiolabeled nanoparticles allowed a quantitative [⁴⁸V]TiO₂NP balancing of all organs, tissues, carcass and excretions of each rat without having to account for chemical background levels possibly caused by dietary or environmental titanium exposure. Highest [⁴⁸V]TiO₂NP accumulations were found in liver (95.5%ID after one day), followed by spleen (2.5%), carcass (1%), skeleton (0.7%) and blood (0.4%). Detectable nanoparticle levels were found in all other organs. The [⁴⁸V]TiO₂NP content in blood decreased rapidly after 24?h while the distribution in other organs and tissues remained rather constant until day-28. The present biokinetics study is part 1 of a series of studies comparing biokinetics after three classical routes of intake (IV injection (part 1), ingestion (part 2), intratracheal instillation (part 3)) under identical laboratory conditions, in order to test the common hypothesis that IV-injection is a suitable predictor for the biokinetics fate of nanoparticles administered by different routes. This hypothesis is disproved by this series of studies.     

Quantitative biokinetics of titanium dioxide nanoparticles after oral application in rats: Part 2

The biokinetics of a size-selected fraction (70?nm median size) of commercially available and ⁴⁸V-radiolabeled [⁴⁸V]TiO₂ nanoparticles has been investigated in female Wistar-Kyoto rats at retention timepoints 1?h, 4?h, 24?h and 7 days after oral application of a single dose of an aqueous [⁴⁸V]TiO₂-nanoparticle suspension by intra-esophageal instillation. A completely balanced quantitative body clearance and biokinetics in all organs and tissues was obtained by applying typical [⁴⁸V]TiO₂-nanoparticle doses in the range of 30–80?μg?kg^?1 bodyweight, making use of the high sensitivity of the radiotracer technique. The [⁴⁸V]TiO₂-nanoparticle content was corrected for nanoparticles in the residual blood retained in organs and tissue after exsanguination and for ⁴⁸V-ions not bound to TiO₂-nanoparticles. Beyond predominant fecal excretion about 0.6% of the administered dose passed the gastro-intestinal-barrier after one hour and about 0.05% were still distributed in the body after 7 days, with quantifiable [⁴⁸V]TiO₂-nanoparticle organ concentrations present in liver (0.09?ng?g^?1), lungs (0.10?ng?g^?1), kidneys (0.29?ng?g^?1), brain (0.36?ng?g^?1), spleen (0.45?ng?g^?1), uterus (0.55?ng?g^?1) and skeleton (0.98?ng?g^?1). Since chronic, oral uptake of TiO₂ particles (including a nano-fraction) by consumers has continuously increased in the past decades, the possibility of chronic accumulation of such biopersistent nanoparticles in secondary organs and the skeleton raises questions about the responsiveness of their defense capacities, and whether these could be leading to adverse health effects in the population at large. After normalizing the fractions of retained [⁴⁸V]TiO₂-nanoparticles to the fraction that passed the gastro-intestinal-barrier and reached systemic circulation, the biokinetics was compared to the biokinetics determined after IV-injection (Part 1). Since the biokinetics patterns differ largely, IV-injection is not an adequate surrogate for assessing the biokinetics after oral exposure to TiO₂ nanoparticles.     

Surface protolytic property characterization of hydroxyapatite and titanium dioxide nanoparticles

We provide characterization data of hydroxyapatite (nHAp) and titanium dioxide (nTiO₂) nanoparticles as potential materials for ion sorption, e.g. in targeted therapy, barrier materials for waste repositories or photovoltaics. The study is focused on the determination of the values of protonation and ion exchange constants and site densities (∑SOH, ∑X; [mol kg⁻¹]) of nTiO₂ and nHAp for further Ra kinetics and sorption experiments. These data are very important for further investigation of the materials, which can be used e.g. as drug delivery systems or in engineered barriers of deep geological repositories. The characterization was based on the evaluation of the dependence of titrating agent consumption on pH. Titration results were evaluated on the basis of several model combinations, however the combination of the Chemical Equilibrium Model (CEM) and Ion Exchange Model (IExM) fits best to the experimental titration curves. However, the differences between the two sorbents were relatively large. Due to stability in a broad pH range and available surface sites, nTiO₂ seems to have a wide application range. The applicability of nHAp is not so wide because of its dissolution under pH 5. Both sorbents are virtually able to sorb cationic species on deprotonated edge and layer sites with different capacities, which can be important for sorption and decontaminating applications.

We provide characterization data of hydroxyapatite (nHAp) and titanium dioxide (nTiO₂) nanoparticles as potential materials for ion sorption, e.g. in targeted therapy, barrier materials for waste repositories or photovoltaics.