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Pathological morphology of different tissues observed under microscope. In mice treated with TiO 2 NPs, neuronal cell degeneration was observed in the brain tissue; vacuoles were observed in the neurons of hippocampus and their number was increased in the high dose groups, which indicated fatty degeneration occurred in the hippocampus of brain tissue. In the lung tissues, perivascular infiltration of inflammatory cells, foamy cells as well as pulmonary fibrosis were observed; the granulomatous lesions were found at the doses of 645 and 1387 mg/ kg. At the doses of 140 and 300 mg/kg, TiO 2 NPs showed vacuolar degeneration in the liver. At 645 mg/kg, inflammatory cells were found in the bile ducts of the liver, and hydropic degeneration around the central vein and spotty necrosis of hepatocytes were also observed. At 645 and 1387 mg/ kg, multifocal lesions were observed in the liver. In the kidneys, swelling in the renal glomerulus was observed in TiO 2 NPs treated mice. In the spleen, minor lesions were observed due to increased proliferation of local macrophages. No obvious abnormality in histology was observed in the heart in TiO 2 NPs treated mice as seen under the microscope (400 6 ). doi:10.1371/journal.pone.0070618.g003
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With a wide range of applications, titanium dioxide (TiO2) nanoparticles (NPs) are manufactured worldwide in large quantities. Recently, in the field of nanomedicine, intravenous injection of TiO2 nanoparticulate carriers directly into the bloodstream has raised public concerns on their toxicity to humans.
In this study, mice were injected intraven...
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... Method. After mixing with a vortex, a single injection of TiO 2 NPs saline suspension was administered through the tail vein (28 G needle). Control group mice were given saline only. Behavior and mortality were monitored and recorded carefully after treatment. 14 days after treatment, blood samples were collected from the femoral artery by a quick incision of the artery while the animal was anesthetized with 2% isoflurane. The animals were then euthanized by cervical dislocation. Serum was obtained by centrifugation at 3500 rpm for 10 minutes and stored at 2 80 u until used. Bone marrow smears were prepared by smearing a mixture of mouse bone marrow from the femur and calf serum on a coated glass slide. Slides were air dried and then fixed in methanol for 15 minutes for the micronucleus test. The organs (heart, lung, liver, spleen, kidneys and brain) were excised and weighed accurately. A small piece of tissue from each organ was dissected, fixed in a 6% formalin solution and stored at 4 u C until used. After weighing the organs, the organ weight/BW coefficients of heart, lung, liver, spleen, kidneys and brain were calculated as organ weight (wet weight, mg)/BW (g) 6 100%. Biochemical parameters detected in blood serum of mice included total bilirubin levels (TBIL), indirect bilirubin (IBIL), direct bilirubin (DBIL), alkaline phosphatase (ALP), alanine aminotransferase (ALT) and aspartate aminotransferase (AST), blood urea nitrogen (BUN), creatinine (CREA), uric acid (URCA) and the enzyme creatine kinase (CK). Hematological parameters examined in this study included WBC count, red blood cell (RBC) count, hemoglobin (HGB), red blood cell specific volume (HCT), mean corpuscular volume (MCV), mean corpuscular hemoglobin (MCH), mean corpuscular hemoglobin concentration (MCHC), red cell distribution width (RDW-CV), platelet (PLT), platelet distribution width (PDW-CV), mean platelet volume (MPV) and plateletcrit (PCT). The fixed tissues were stored at 4 C overnight and then embedded in paraffin blocks. 4 m m thick tissue sections were prepared and stained with hematoxylin and eosin (H&E). Histopathological morphology was checked under the microscope by an independent pathologist. The methanol fixed bone marrow smears were stained with Giemsa stain according to the conventional method. One thousand polychromatic erythrocytes per animal were analyzed for the presence of micronucleus in cells. Cyclophosphamide (20 mg/kg, two intraperitoneal injections, at 24 and 48 h before mice were sacrificed, respectively) was used as a positive control. Results were expressed as mean 6 standard deviation (SD). Multigroup comparisons of the means were carried out by one- way analysis of variance (ANOVA) test. Dunnett’s test was used to compare the difference between the experimental groups and the control group. The statistical significance for all tests was set at P , 0.05. The average size distribution of TiO 2 NPs was 42.30 6 4.60 nm as detected by optimas 6.5 image analysis software. Image of TiO 2 NPs was captured by SEM (Figure 1). The size distribution of TiO 2 NP aggregates in saline was observed under the light microscope (Figure 2). 7 days after treatment, difference in eating and drinking patterns and physical activity were observed in the 1387 mg/kg dose group. They showed decreased food and water intake and decreased physical activity than control group. At day 9, 2 males and 4 females in the 1387 mg/kg dose group died. 2 males survived at this dose level, leaving less than three mice at the end of the experiment. Therefore, in this dose group only the tissues were histopathologically analyzed. Data were expressed as means 6 SD (n = 4) (Table 2). Comparisons were carried out by one-way variance test (SNK’s multiple comparison tests). Compared to control, coefficients of the spleens in TiO 2 NPs treated mice increased significantly; however, coefficients of the liver and kidney decreased significantly. No significant effects were observed in the coefficients of the heart, lung or brain in TiO NPs treated mice. Biochemical parameters in the serum as detected by the autoanalyzer are listed in Table 3. No significant differences were found in the serum levels of TBIL, ALT, AST, ALP, BUN, CREA, or CK in TiO 2 NPs treated mice as compared to the control group. The levels of DBIL and IBIL in TiO 2 NPs treated mice decreased in a dose dependent manner. The level of URCA in TiO 2 NPs treated mice at 140 and 300 mg/kg were significantly increased compared to the control group. Hematological parameters in the blood as detected by the autoanalyzer are listed in Table 4. Intravenous injection of high doses of TiO 2 NPs did not induce significant acute hematological toxicity except for an increase in the WBC count in 645 mg/kg dose group. Histopathological examination of the tissues indicated that intravenous administration of high doses of TiO 2 NPs could induce multi-organ pathological lesions in a dose dependent manner (Figure 3). The results show that TiO 2 NPs treatment could induce different degrees of damage in the brain, lung, spleen, liver and kidneys. However, no obvious pathological effects were observed in the heart of TiO NPs treated mice. Micronucleus test result 14 days after a single intravenous injection of different doses of TiO 2 NPs shows, no significant increase in micronucleus cell number in the polychromatic erythrocytes among TiO 2 NPs treated mice as compared to the control (Figure 4). Studies have demonstrated that accumulation of TiO 2 NP can be observed in the liver, lung, kidneys, and spleen after intraperitoneal, intravenous or dermal administration.[13–15] After inhalation exposure in rats, TiO 2 NPs have been found to accumulate in the lung, leading to phagocytosis [16,17]. Wang et al. [18] found that a single oral gavage exposure of a very high dose (5 g/kg) of TiO 2 NPs (80 nm) in mice could elevate the ALT/AST enzyme ratio and LDH level in serum, which implies TiO 2 NPs may induce hepatic injury. Fabian et al. [12] reported the accumulation of TiO 2 NPs in the liver, spleen, lung, and kidneys after intravenous administration of 5 mg/kg TiO 2 NPs in rat. However, there were no remarkable toxic effects observed in these organs. In this study, behavioral and physical symptoms of acute toxicity such as decreased activity or decreased uptake of food and water were observed in the first week in the mice treated with 1387 mg/ kg of TiO 2 NPs. The behavior of the mice in the other dose groups was normal throughout the study. Compared to the control group, organ coefficients of the spleens in TiO 2 NPs treated mice increased significantly; while, the organ coefficients of the liver and kidneys decreased significantly. Both increase and decrease of the organ coefficients may be caused by TiO 2 NPs excretion or accumulation in the organs, which could cause certain histopathological changes. These changes were confirmed in the histopathological tissue sections of the liver and kidneys. The liver tissue showed hepatocyte vacuolar degeneration, spotty necrosis of liver hepatocytes, along with inflammatory cell invasions in the bile ducts of the liver, and hydropic degeneration around the central vein. At higher doses, multifocal lesions were also observed in the liver. Wang et al. [18] reported that TiO 2 NPs treatment through oral administration could increase hepatocyte necrosis. Combined with our results, it can be concluded that TiO 2 NPs can induce hepatocyte injury in vivo . In the kidneys, swelling in the renal glomerulus in TiO 2 NPs treated mice was observed. Serum biochemical analysis showed a significant increase in blood URCA level in TiO 2 NPs treated mice. URCA is the end product of decomposition of a purine nucleic acid, which is mainly excreted from the kidneys. Blood URCA levels are elevated in renal dysfunction [19]. In the spleen, TiO 2 NPs treatment caused increased proliferation of local macrophages, which is consistent with the results of the increased organ coefficients. Although no significant changes were found in the organ coefficients for brain and lung tissues in TiO 2 NPs treated mice, histopathological examination showed certain lesions. The brain tissue showed neuronal cell degeneration and vacuoles were observed in the hippocampus, which is indicative of fatty degeneration in the hippocampus. In the lung tissues, inflammatory cells, foamy cells and granulomatous lesions were observed. Park at al. [20] reported that granulomatous lesions were found in the bronchiole and alveoli of the lung after 14 days TiO 2 NPs treatment (5 mg/kg, 20 mg/kg, and 50 mg/kg) in mice. Rours- gaard et al. [21] also found inflammation in the lungs after TiO 2 NPs treatment in mice by intratracheal instillation. Bilirubin consists of TBIL, IBIL, and DBIL. Studies have revealed that the levels of serum bilirubin are inversely related to the risk of certain heart diseases [22]. The results showed that both IBIL and DBIL significantly decreased in TiO 2 NPs treated mice compared to the control mice, which suggests that TiO 2 NPs treatment might also have myocardial effects. However, histopathological examination of the heart showed no pathological effects and no significant changes in the organ coefficients in the TiO 2 NPs treated mice in this study. These differences may be attributed to late onset of histological evidence of myocardial pathology. Hematological analysis is normally used to detect the hematological toxicity of different chemicals. In this study, the results indicated that, 14 days after intravenous administration of the high dose of TiO 2 NPs, no significant hematological toxicity could be observed. The micronucleus test is frequently used as a tool for genotoxicity assessment of various chemicals. It is easier to conduct than the chromosomal aberration test in terms of procedures and evaluation. In this study, 14 days after a single intravenous injection of different doses of ...
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Background:
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Citations
... In this experimental research, 50 female NMRI mice aged 8-12 weeks and weighing 25-30 g were obtained from the ACE -Animal Care in Egypt. The animals were housed under settings that included 12 hrs. of light and 12 hrs. of darkness, a temperature of 22-26 o C, and free access to water and commercial pelleted food throughout the course of the study [30]. The mice were then distributed at random into five groups of 10. ...
... Metal oxide NPs and nanocomposites (NCs) have been applied in cancer therapy, as reported in many studies. 29,33,[52][53][54][55] In the present work, the anticancer activities of synthesized NPs at different concentrations (3.125-200 mg ml −1 ) against HTC 116 cells and NCs were assessed using MTT assay in the dark aer 24 h and 48 h of exposure, respectively. As shown in Fig. 8a and b, the prepared TiO 2 NPs exhibited high toxicity at high concentrations aer 24 h and 48 h compared with the control group. ...
... The SEM image of TiO 2 NPs(Fig. 3a)displays that the particles of TiO 2 NPs were uniform with a smooth surface, matching with earlier studies.[28][29][30] Thus, theFig. 2 TEM characterization: TiO 2 NPs (a), ZnO NPs (b), ZnO-TiO 2 NCs (c), and ZnO-TiO 2 /RGO NCs (d). ...
The purpose of the present study is to enhance the anticancer and biocompatibility performance of TiO2 NPs, ZnO NPs, ZnO-TiO2 (NCs), and ZnO-TiO2/reduced graphene oxide (RGO) NCs against two types of human cancer (HCT116) and normal (HUVCE) cells. A novel procedure for synthesizing ZnO-TiO2/RGO NCs has been developed using Senna surattensis extract. The improved physicochemical properties of the obtained samples were investigated using different techniques such as XRD, TEM, SEM, XPS, FTIR, DLS and UV-visible spectroscopy. XRD results showed that the addition of ZnO and RGO sheets affects the crystal structure and phase of TiO2 NPs. SEM and TEM images displayed that the TiO2 NPs and ZnO NPs were small with uniform spherical morphology in the prepared ZnO-TiO2/RGO NCs. Besides, it is shown that ZnO-TiO2 NCs anchored onto the surface of RGO sheets with a particle size of 14.80 ± 0.5 nm. XPS data confirmed the surface chemical composition and oxidation states of ZnO-TiO2/RGO NCs. Functional groups of prepared NPs and NCs were determined using FTIR spectroscopy. DLS data confirmed that the addition of ZnO and RGO sheets improves the negative surface charge of the prepared pure TiO2 NPs (−22.51 mV), ZnO NPs (−18.27 mV), ZnO-TiO2 NCs (−30.20 mV), and ZnO-TiO2/RGO NCs (−33.77 mV). Optical analysis exhibited that the bandgap energies of TiO2 NPs (3.30 eV), ZnO NPs (3.33 eV), ZnO-TiO2 NCs (3.03 eV), and ZnO-TiO2/RGO NCs (2.78 eV) were further enhanced by adding ZnO NPs and RGO sheets. This indicates that the synthesized samples can be applied to cancer therapy and environmental remediation. The biological data demonstrated that the produced ZnO-TiO2/RGO NCs show a more cytotoxic effect on HCT116 cells compared to pure TiO2 NPs and ZnO-TiO2 NCs. On the other hand, these NCs displayed the lowest level of toxicity towards normal HUVCE cells. These results indicate that the ZnO-TiO2/RGO NCs have strong toxicity against HCT116 cells and are compatible with normal cells. Our results show that the plant extract enhanced the physicochemical properties of NPs and NCs compared with the traditional chemical methods for synthesis. This study could open new avenues for developing more effective and targeted cancer treatments.
... 9,10 Thus, tattoo inks, in particular the pigments, can be expected in all organs and indeed, were reported in the lymph nodes located next to the tattoo. [11][12][13][14][15][16][17] Specifically, the accumulation of particles in Kupffer cells of mice liver was suggested by observation with transmission electron microscopy (TEM) images taken after tattooing with black and red inks. 18 Nevertheless, the extent and the relevance of pigment transportation to other organs of the human body is still unknown, so are, consequently, possible related health risks. ...
Tattooing has been part of the human culture for thousands of years, yet only in the past decades has it entered the mainstream of the society. With the rise in popularity, tattoos also gained attention among researchers, with the aim to better understand the health risks posed by their application. ‘A medical‐toxicological view of tattooing’—a work published in The Lancet almost a decade ago, resulted from the international collaboration of various experts in the field. Since then, much understanding has been achieved regarding adverse effects, treatment of complications, as well as their regulation for improving public health. Yet major knowledge gaps remain. This review article results from the Second International Conference on Tattoo Safety hosted by the German Federal Institute for Risk Assessment (BfR) and provides a glimpse from the medical‐toxicological perspective, regulatory strategies and advances in the analysis of tattoo inks.
... however, leakage of metal nanoparticles (MetNPs) into aquatic ecosystems at high concentrations can cause toxicity to aquatic animals (Matranga andcorsi 2012, Mirghaed et al. 2018). in general, it is very difficult to determine the amount and form of nanoparticles in natural environments, however, studies have shown that the amount of MetNPs in nature can vary from ng/l to mg/l (Fabrega et al. 2011). in marine environments, a range of 0.021-40 µg/l is reported for tiNPs (Dedman et al. 2021). toxicological studies have demonstrated that tiNPs can cause toxicity in a wide range of organisms including bacteria, invertebrates, and vertebrates (sharma 2009, Xu et al. 2013, Yang et al. 2013, hou et al. 2019a, 2019b. in fish, the use of tiNPs in diet or water has caused toxicity, which its severity may be different with nanoparticle concentration, exposure time, and experimental conditions (Bar-ilan et al. 2012, Della torre et al. 2015, carmo et al. 2019, canli and canli 2020. similar to fish, many studies have studied the toxicity of nanoparticles in bivalves (canesi et al. 2012, libralato et al. 2013, Girardello et al. 2016, li et al. 2021, Javanshir Khoei and Rezaei 2022). ...
... The observed decrease in RBCs and PLT levels indicates that NPTiO2 may have an adverse effect on blood coagulation and lead to damage of the hematopoietic system (Vasantharaja and Reddy 2015). This is consistent with previous reports showing that treatment of rats with NPTiO2 resulted in decreased RBCs and Hb levels compared to the control group (Xu et al. 2013). Moreover, studies have demonstrated that free radicals generated by nanoparticle action may be the main cause of destruction of RBCs and mature cells (Ferdous and Nemmar 2020). ...
Olive oil, particularly monovarietal virgin olive oil (MVOO), has garnered significant attention due to its potential health benefits attributed to a rich composition of bioactive compounds. This study aimed to assess the composition of bioactive compounds and the antioxidant activity of monovarietal virgin olive oil (MVOO). Specifically, the objective was to investigate the protective effects of MVOO in alleviating the adverse effects induced by titanium dioxide nanoparticles (NPTiO2). Bioactive compounds in MVOO were analyzed using UV–visible spectrophotometry, along with High-Performance Liquid Chromatography with a Photodiode Array (HPLC–PDA) for a comprehensive assessment. Antioxidant activity in vitro was evaluated through 2,2-diphenyl-1-picrylhydrazyl (DDPH) assays and on rats in vivo. A total of twenty-four male Wistar albino rats were randomly divided into four groups: one served as the control (Control), and the three remaining groups were injected with NPTiO2. Among the NPTiO2-injected groups, one received no treatment (NPTiO2), while the other two (NPTiO2 + MVOO1 and NPTiO2 + MVOO2) were treated with different doses of MVOO (2 g/kg bw and 6 g/kg bw). Commencing 24 h after NPTiO2 injection, the treatment with MVOO began, and body weight was consistently recorded. After 6 weeks of dietary manipulation, the fasting animals were sacrificed, and evaluations of hematological parameters, biochemical parameters, and oxidative stress markers in the liver and kidney were conducted. Histological examinations were performed to confirm protective effects. The analysis revealed significant levels of bioactive compounds in MVOO, with a remarkable DDPH antioxidant activity of 87.70%. Additionally, HPLC–PDA revealed the presence of quercetin and cinnamic acid. NPTiO2 induced oxidative stress, evidenced by increased biochemical parameters and elevated malondialdehyde levels in the liver and kidney (by + 91.30% and + 89.47%, respectively). Furthermore, there was a notable decrease in both hepatic and renal glutathione concentrations (-42% and -60%, respectively) and a reduction in antioxidant enzyme activities (GPx: -54.64% and -85.31%, GST: -77.70% and -74.33%, CAT: -87.21% and -73.11% for hepatic and renal, respectively), compared to the control group. Hematological profiles showed a decline in red blood cells and hemoglobin (-32.02%). Treatment with MVOO exhibited a protective effect by effectively mitigating biochemical parameters and enhancing antioxidant enzyme activities in the NPTiO2 + MVOO1 and NPTiO2 + MVOO2 groups, compared to the NPTiO2 group. Histological findings confirmed the protective effects of MVOO on liver and kidney damage caused by NPTiO2. MVOO demonstrated a potent protective effect against NPTiO2-induced oxidative stress, attributed to its richness in bioactive compounds.
... The increase in RBC and Hb caused an increase in PCV (Short et al., 2012), and results showed that PCV also increased from 31 to 39%. The increased spleen weight (Figure 2) might cause increased WBC and RBC production (Xu et al., 2013). These hematological changes in hematological parameters are probably caused by FNC accumulation in organs like the thymus and spleen and retention in the PBMC (Sun et al., 2020). ...
Objectives:
The present study aimed to provide an insight into the acute toxicity of a novel fluorinated nucleoside analogue (FNA), FNC (Azvudine or2'-deoxy-2'-β-fluoro-4'-azidocytidine). FNC showed potent anti-viral and anti-cancer activities and approved drug for high-load HIV patients, despite, its acute toxicity study being lacking.
Materials and methods:
OECD-423 guidelines were followed during this study and the parameters were divided into four categories - behavioral parameters, physiological parameters, histopathological parameters, and supplementary tests. The behavioral parameters included feeding, body weight, belly size, organ weight and size, and mice behavior. The physiological parameters consisted of blood, liver, and kidney indicators. In histopathological parameters hematoxylin and eosin staining was performed to analyse the histological changes in the mice organs after FNC exposure. In addition, supplementary tests were conducted to assess cellular viability, DNA fragmentation and cytokine levels (IL-6 and TNF-α) in response to FNC.
Results:
In the behavioral parameters FNC induced changes in the mice-to-mice interaction and activities. Mice's body weight, belly size, organ weight, and size remained unchanged. Physiological parameters of blood showed that FNC increased the level of WBC, RBC, Hb, and neutrophils and decreased the % count of lymphocytes. Liver enzymes SGOT (AST), and ALP was increased. In the renal function test (RFT) cholesterol level was significantly decreased. Histopathological analysis of the liver, kidney, brain, heart, lungs, and spleen showed no sign of tissue damage at the highest FNC dose of 25 mg/kg b.wt. Supplementary tests for cell viability showed no change in viability footprint, through our recently developed dilution cum-trypan (DCT) assay, and Annexin/PI. No DNA damage or apoptosis was observed in DAPI or AO/EtBr studies. Pro-inflammatory cytokines IL-6 and TNF-α increased in a dose-dependent manner.
Conclusion:
This study concluded that FNC is safe to use though higher concentration shows slight toxicity.
... Alterations in organ weight are recognized as a sensitive indicator of potential toxic effects in organ integrity, being assessed through organ-to-body weight ratios (tissue index). Elevated values indicate organ hypertrophy, edema or congestion and, in turn, a decreased tissue index indicates organ atrophy and degeneration Pinho et al., 2021a;Sellers et al., 2007;Xu et al., 2013). Here, no major differences between groups were observed in terms of tissue index, denoting the safety of tested formulations. ...
Melanoma is the most aggressive form of skin cancer, with increasing incidence and mortality rates. To overcome current treatment limitations, a hybrid molecule (HM) combining a triazene and a ʟ-tyrosine analogue, was recently synthesized, incorporated in long blood circulating liposomes (LIP HM) and validated in an immunocompetent melanoma model. The present work constitutes a step forward in the therapeutic assessment of HM formulations. Here, human melanoma cells, A375 and MNT-1, were used and dacarbazine (DTIC), a triazene drug clinically available as first-line treatment for melanoma, constituted the positive control. In cell cycle analysis, A375 cells, after 24-h incubation with HM (60 μM) and DTIC (70 μM), resulted in a 1.2 fold increase (related to control) in the percentage of cells in G0/G1 phase. The therapeutic activity was evaluated in a human murine melanoma model (subcutaneously injected with A375 cells) to most closely resemble the human pathology. Animals treated with LIP HM exhibited the highest antimelanoma effect resulting in a 6-, 5- and 4-fold reduction on tumor volume compared to negative control, Free HM and DTIC groups, respectively. No toxic side effects were detected. Overall, these results constitute another step forward in the validation of the antimelanoma activity of LIP HM, using a murine model that more accurately simulates the pathology that occurs in human patients.
... Organ weight variations are commonly accepted as a good indicator of possible chemically induced changes, usually preceding morphological changes [38,39]. Thus, the comparison of the weight of the different organs of interest, through the tissue index, between the different groups of animals in an experiment, has been a tool used by several researchers for a first toxicological evaluation of the tested compounds [30,35,71,[94][95][96]. While increased tissue index values may reflect organ hypertrophy, edema or congestion, decreased values may imply atrophy or degenerative changes [96]. ...
In recent years, gold nanoparticles (AuNPs) have aroused the interest of many researchers due to their unique physicochemical and optical properties. AuNPs are being explored in a variety of biomedical fields, either in diagnostics or therapy, particularly for localized thermal ablation of cancer cells after light irradiation. Besides the promising therapeutic potential of AuNPs, their safety constitutes a highly important issue for any medicine or medical device. For this reason, in the present work, the production and characterization of physicochemical properties and morphology of AuNPs coated with two different materials (hyaluronic and oleic acids (HAOA) and bovine serum albumin (BSA)) were firstly performed. Based on the above importantly referred issue, the in vitro safety of developed AuNPs was evaluated in healthy keratinocytes, human melanoma, breast, pancreatic and glioblastoma cancer cells, as well as in a three-dimensional human skin model. Ex vivo and in vivo biosafety assays using, respectively, human red blood cells and Artemia salina were also carried out. HAOA-AuNPs were selected for in vivo acute toxicity and biodistribution studies in healthy Balb/c mice. Histopathological analysis showed no significant signs of toxicity for the tested formulations. Overall, several techniques were developed in order to characterize the AuNPs and evaluate their safety. All these results support their use for biomedical applications.
... Thrombus formation and platelet aggregation were triggered by TiO 2 NPs rutile but not anatase form [85]. In contrast, the intravenous injection of TiO 2 NPs (140, 300, 645 mg/kg) had no effects on hematological parameter except white blood cells that was increased [86]. TiO 2 NPs (intraperitoneal at 20 mg/kg doses every 2 days for 20 days) affect platelets count while other hematological parameters were not affected [87]. ...
Background: Over the last decades, the exposure to titanium dioxide nanoparticles (TiO 2 NPs) has increased due to the wide application in industry, food adduct, medicine, cosmetic products, etc. Literature review showed that the TiO 2 NPs exert toxic effects on several organs.
Methods: We searched PubMed, MEDLINE and the other databases with the following keywords, "titanium dioxide nanoparticle", "TiO 2 NPs", "myocardial infarction", "endothelial", "blood pressure", "heart" and "cardiovascular", and reviewed the literature by focusing on the toxic effects of TiO 2 NPs on the cardiovascular system, and possible underlying mechanism.
Results: The toxic effects of TiO 2 NPs on the cardiovascular system are controversial but some possible mechanisms were proposed. TiO 2 NPs and nanoparticle-derived titanium induce cardiac injury, endothelial dysfunction and increase blood pressure and heart rate. These effects are mediated via systemic or local oxidative stress and inflammation.
Conclusion: The TiO 2 NPs toxicity is dependent on cell type and particle characteristic, and the controversial results may be due to these variables. However, a growing body of evidence confirmed the possible TiO 2 NPs toxicity on the cardiovascular system.
... Thrombus formation and platelet aggregation were triggered by TiO 2 NPs rutile but not anatase form [85]. In contrast, the intravenous injection of TiO 2 NPs (140, 300, 645 mg/kg) had no effects on hematological parameter except white blood cells that was increased [86]. TiO 2 NPs (intraperitoneal at 20 mg/kg doses every 2 days for 20 days) affect platelets count while other hematological parameters were not affected [87]. ...
Background
Over the last decades, the exposure to titanium dioxide nanoparticles (TiO2 NPs) has increased due to the wide application in industry, food adduct, medicine, cosmetic products, etc. Literature review showed that the TiO2 NPs exert toxic effects on several organs.Methods
We searched PubMed, MEDLINE and the other databases with the following keywords, "titanium dioxide nanoparticle", "TiO2 NPs", "myocardial infarction", "endothelial", "blood pressure", "heart" and "cardiovascular", and reviewed the literature by focusing on the toxic effects of TiO2 NPs on the cardiovascular system, and possible underlying mechanism.ResultsThe toxic effects of TiO2 NPs on the cardiovascular system are controversial but some possible mechanisms were proposed. TiO2 NPs and nanoparticle-derived titanium induce cardiac injury, endothelial dysfunction and increase blood pressure and heart rate. These effects are mediated via systemic or local oxidative stress and inflammation.Conclusion
The TiO2 NPs toxicity is dependent on cell type and particle characteristic, and the controversial results may be due to these variables. However, a growing body of evidence confirmed the possible TiO2 NPs toxicity on the cardiovascular system.
