Considerable differences in pulmonary responses have been observed in animals exposed to cerium dioxide nanoparticles via inhalation. These differences in pulmonary toxicity might be explained by differences in lung deposition, species susceptibility or physicochemical characteristics of the tested cerium dioxide nanoforms (i.e. same chemical substance, different size, shape, surface area or surface chemistry). In order to distinguish the relative importance of these different influencing factors, we performed a detailed analysis of the data from several inhalation studies with different exposure durations, species and nanoforms, namely published data on NM211 and NM212 (JRC repository), NanoAmor (commercially available) and our published a...
International audienceThe exact role of primary nanoparticle (NP) size and their degree of agglomera...
Frequent use of cerium dioxide nanoparticles e.g. as diesel fuel additive requires assessment of pos...
The deposition characteristics in lungs following inhalation, the potential toxic effects induced an...
Considerable differences in pulmonary responses have been observed in animals exposed to cerium diox...
Considerable differences in pulmonary responses have been observed in animals exposed to cerium diox...
There are many uncertainties regarding the hazard of nanosized particles compared to the bulk materi...
Development and manufacture of nanomaterials is growing at an exponential rate, despite an incomplet...
Ceria nanoparticles (nano-ceria) have recently gained a wide range of applications, which might pose...
Background: Nanomaterials like cerium oxide and barium sulfate are frequently processed in industria...
Background: Animal models remain at that time a reference tool to predict potential pulmonary advers...
Little is known about the mechanisms involved in lung inflammation caused by the inhalation or insti...
A number of studies have shown that induction of pulmonary toxicity by nanoparticles of the same che...
Objectives: With recent advances in nanoparticle manufacturing and applications, potential exposure ...
Lung carcinogenicity and putative systemic effects of low-dose life-time inhalation exposure to biop...
International audienceThe exact role of primary nanoparticle (NP) size and their degree of agglomera...
Frequent use of cerium dioxide nanoparticles e.g. as diesel fuel additive requires assessment of pos...
The deposition characteristics in lungs following inhalation, the potential toxic effects induced an...
Considerable differences in pulmonary responses have been observed in animals exposed to cerium diox...
Considerable differences in pulmonary responses have been observed in animals exposed to cerium diox...
There are many uncertainties regarding the hazard of nanosized particles compared to the bulk materi...
Development and manufacture of nanomaterials is growing at an exponential rate, despite an incomplet...
Ceria nanoparticles (nano-ceria) have recently gained a wide range of applications, which might pose...
Background: Nanomaterials like cerium oxide and barium sulfate are frequently processed in industria...
Background: Animal models remain at that time a reference tool to predict potential pulmonary advers...
Little is known about the mechanisms involved in lung inflammation caused by the inhalation or insti...
A number of studies have shown that induction of pulmonary toxicity by nanoparticles of the same che...
Objectives: With recent advances in nanoparticle manufacturing and applications, potential exposure ...
Lung carcinogenicity and putative systemic effects of low-dose life-time inhalation exposure to biop...
International audienceThe exact role of primary nanoparticle (NP) size and their degree of agglomera...
Frequent use of cerium dioxide nanoparticles e.g. as diesel fuel additive requires assessment of pos...
The deposition characteristics in lungs following inhalation, the potential toxic effects induced an...