Abstract
Nonporous silica nanoparticles (SiNPs) are promising drug carrier platforms for intraocular drug delivery. In this study, we investigated the safety of three different sizes of SiNPs (50, 100, and 150 nm) in a human corneal endothelial cell (HCEC) line, B4G12. The HCECs were exposed to different concentrations (0, 25, 50, and 100 µg/ml) of three sizes of SiNPs for up to 48 h. Cellular viability, autophagy, lactate dehydrogenase (LDH) assay, and mammalian target of rapamycin (mTOR) pathway activation were evaluated. Intracellular distribution of the SiNPs was evaluated with transmission electron microscopy (TEM). TEM revealed that the SiNPs were up-taken by the HCECs inside cytoplasmic vacuoles. No mitochondrial structural damage was observed. Both cellular viability and LDH level remained unchanged with up to 100 µg/mL of SiNP treatment. Autophagy showed a significant dose-dependent activation with 50, 100, and 150 nm SiNPs. However, the mTOR activation remained unchanged. Human corneal tissue culture with 100 µg/ml concentrations of SiNPs for 72 h revealed no significant endothelial toxicity. In vivo corneal safety of the SiNPs (0.05 ml intracameral injection, 200 mg/ml concentration) was also verified in rabbit models. These findings suggested that 50, 100, and 150 nm SiNPs did not induce acute significant cytotoxicity in corneal endothelial cells at concentrations up to 100 µg/mL. However, long-term toxicity of SiNPs remains unknown.
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Introduction
Human corneal endothelial cells (HCECs) comprise a monolayer of cells located in the innermost area of the cornea. HCECs are important in maintaining corneal transparency through their role in ionic pumping (Na+/K+ pump)1,2. They normally do not divide to replace injured cells in vivo. Therefore, significant injury or loss of HCECs eventually result in severe corneal edema and loss of transparency2.
Amorphous silica nanoparticles (SiNPs) are commonly used as additives to cosmetics, printer toners, packaging, and imaging3. They are actively being investigated as promising nanocarrier systems for drug delivery to various human tissues3. The large surface area to volume ratio, a stable chemical structure, and ease of surface modification increased the attractiveness of SiNPs as promising drug carrier system3. However, biodegradability and biocompatibility of SiNPs should be considered for safer and reliable biologic applications because retaining of SiNPs in human body can cause undesirable long-term health effect. Recently, biodegradable hollow mesoporous types of SiNPs were introduced for more safe effective drug carrier4,5.
SiNPs are one of the promising intraocular drug delivery platforms6. The recent observation that corneas are permeable to small sizes (5–50 nm) of SiNPs suggests their use as an ophthalmic drug delivery system7. However, the possible cytotoxicity is a concern. SiNPs are known to induce biological effects and cellular toxicity depending on the SiNP size, concentration, and cell type8,9. Previously, our group reported the effect of various sizes of SiNPs on cultured human corneal epithelial cells and keratocytes. We verified the lack of significant cytotoxicity of 50, 100, and 150 nm SiNPs up to a concentration of 100 µg/ml in culture media10,11.
SiNP-based ophthalmic medication can reach intraocular space by topical application or intraocular injection into the anterior chamber or vitreous cavity. Regardless of the route of administration, the major clearance of intraocular SiNP can be through an aqueous outflow pathway12. Therefore, a significant contact between SiNPs and HCECs is expected, and the safety issue of HCECs is raised.
To further extend our previous studies, monodisperse nonporous SiNPs with diameters of 50, 100, and 150 nm were employed to investigate how particle size and concentration affect the biological activities of HCECs. Specifically, the effect of different sizes and concentrations of SiNPs on critical biological responses, including cellular viability and autophagy, was evaluated. Furthermore, the effect of SiNPs on the mammalian target of rapamycin (mTOR) pathway, the upstream cellular proliferative pathway, was investigated. Finally, human ex vivo corneas and in vivo rabbit models were used to verify the safety of SiNPs in corneal endothelial cells.
Results
Characterization of SiNPs
The morphologies of each SiNP used in this study were observed by scanning electron microscope (SEM), and the size distribution graphs were previously reported11. The average sizes of SiNPs were measured as 50.68, 102.81, and 149.41 nm11. Dispersity of the nanoparticles was determined on the basis of the coefficient of variation. Nanoparticles with under a 5% coefficient of variation were defined as monodisperse nanoparticles. The stability of SiNPs in different aqueous solutions was investigated as the measurement of the zeta potential. In distilled water, the SiNPs showed a high zeta potential of over −50 mV and this means good stability and dispersion. In comparison, the SiNPs dispersed in Dubelco’s phosphate-buffered saline (DPBS) showed a lower zeta potential close to a neutral charge. The significant change of zeta potential of the SiNPs means the offset by various salts contained in DPBS. Our result also demonstrated that the charges of the SiNPs are almost neutral in a cell culture medium and this suggested SiNPs are prone to agglomeration in culture medium (Table 1)10.
Intracellular Distribution of SiNPs
Transmission electron microscopy (TEM) revealed that SiNPs were localized primarily in cytoplasmic vesicles of HCECs (Fig. 1). No SiNPs were observed inside the mitochondria. Mitochondria and nuclear membrane remained intact with the treatment of SiNPs (Fig. 1).
Cellular Viability and Lactate Dehydrogenase (LDH) Assay
In general, the viability of HCECs did not significantly change because of exposure to SiNPs (Fig. 2). Mild increases in the viability of HCECs were observed sporadically, as shown in Fig. 2, with 50 µg/mL of 50 nm SiNPs after 24 h of incubation. In addition, LDH, which is released through cell membrane damage, showed no increase with the treatment by SiNPs (Fig. 3). A mild decrease in LDH release was specifically observed in 50 nm SiNPs after 48 h of incubation.
Cellular Autophagy
The autophagy marker (LC3A/B) was used to investigate the effect of SiNPs on the cellular autophagy system (Fig. 4). With the activation of autophagy, LC3A/B II increased relative to LC3A/B I. The SiNP addition triggered a significant dose-dependent increase in the LC3A/B II protein expression, and this phenomenon was observed in all three sizes of SiNPs, especially at the 100 μg/mL of concentration. The activation of autophagy was also demonstrated by the increased LC3B proteins in the cytoplasm as a result of the SiNPs treatment, and this was shown by the immunocytochemical analysis (Fig. 5).
mTOR Pathway Activation
We measured the expression level of phosphorylated mTOR (p-mTOR) and mTOR (Fig. 4). The increase in phosphorylated mTOR indicated the activation of the pathway. The expression of p-mTOR showed no significant change with the SiNP addition when compared with the normal control. Our finding suggests that 50, 100, and 150 nm SiNPs do not inhibit mTOR signal transduction, which is one of the most important cell survival pathways.
Ex Vivo HCEC Toxicity Assay
We used a low concentration of trypan blue (0.005%) mixed with minimum essential media (MEM) to minimize the endothelial cell toxicity during the staining procedure13. The trypan blue-stained area showed no significant difference compared with the baseline in all SiNP-treated corneas after 72 h of incubation (Fig. 6). After the SiNP treatment, the corneal endothelial cells effectively maintained a normal hexagonal actin skeleton, as revealed by the phalloidin staining (Fig. 6).
In Vivo Corneal Endothelial Cell Toxicity Assay
The rabbit corneas maintained their transparency for two weeks after the intracameral injection of SiNPs. No corneal haze, edema, or limbal vascular abnormality was observed both in the control and in the SiNP-treated eyes. The iris appeared normal, and the crystalline lens was clear both in the control and in the SiNP-treated eyes. The hexagonal structure of corneal endothelium was well maintained, and no significant difference was found in the endothelial cell density between the control and treated groups (Fig. 7). The histopathologic evaluation revealed no difference in the corneal endothelial appearance between SiNPs-treated and control corneas (Fig. 7).
Discussion
In this study, we found that monodisperse nonporous SiNPs of 50, 100, and 150 nm sizes induced no significant cytotoxicity in cultured HCECs up to 48 h and at a concentration of up to 100 µg/mL. Cellular autophagy showed a dose-dependent increase with high concentrations of SiNPs, but the mTOR pathway remained intact. The human corneal tissue culture model demonstrated no significant cytotoxicity of SiNPs (100 µg/mL) after 72 h of exposure. The safety of SiNPs was further verified in vivo with the rabbit intracameral injection model.
For efficient intraocular drug delivery, nanoparticle-based ocular drug delivery systems, including gold, carbon, lipid, chitosan, liquid crystalline, and albumin nanoparticles, have been actively investigated14,15,16,17,18,19. As a nanocarrier system, SiNPs have a great potential for ocular drug delivery20,21. SiNPs have a stable chemical structure, a large surface area to volume ratio, ease of surface modification, and tolerable biodegradability, which all increase their attractiveness for biologic applications3. However, safety must be verified22, and as mentioned earlier, the safety of SiNPs has always been a challenge for clinical application. The crystalline form of silica is toxic to alveolar cells and can induce irreversible pulmonary silicosis23,24. Conversely, amorphous silica, such as nonporous silica particle, is considered relatively biologically safe because of its biodegradability25,26,27. Biodegradation and clearance are essential for biomedical use of nanoparticles because chronic accumulation of nanoparticles in human bodies can lead to serious long term complications. It was reported that 5 to 10 nm sized nonporous SiNPs degraded in two weeks28. Furthermore, smaller and porous SiNPs degraded faster than larger and nonporous SiNPs28. It was reported that mesoporous SiNPs biodegraded in human umbilical vein endothelial cells and human embro kidney (HEK) 293 T cells29,30. Nevertheless, negative reports have suggested the significant nanotoxicity caused by SiNPs31,32,33,34,35. The nanotoxicity of SiNPs seems to be dependent on size, dose, and cell types9,36. Therefore, the toxicity of silica nanoparticles should be evaluated independently in every target organ system by means of both in vivo and in vitro toxicity tests. For the ocular system, no direct toxicity of SiNPs in retinal and corneal cells has been previously reported6,37. In addition, our group recently reported the in vitro safety of 50, 100, and 150 nm-sized nonporous SiNPs by using the primary culture of human corneal epithelium and keratocytes10,11.
Although, the lack of acute toxicity of SiNPs on cultured human corneal epithelial cells and keratocytes was verified in our previous reports10,11, further verification of the safety of SiNPs in HCECs is madatory. Corneal epithelial cells and keratocytes possess regenerative capability and they can actively repopulate the damaged cells within several weeks after the injury. However, HCECs are lack of regenerative potential and any injury to HCECs can lead to the irreversible loss of corneal transparency and serious visual deterioration2. After penetrating the cornea, all nanoparticles disperse into aqueous humor. The aqueous outflow pathway is the most important clearance pathway for intraocular porous silicon micro-particles12. Until full clearance is obtained through the trabecular meshwork, SiNPs can remain in contact with HCECs for a prolonged time. Therefore, our current study regarding HCEC safety is an important step in the safety clearance for the future development of SiNPs as an ocular topical drug delivery system.
In this study, SiNPs treatment increased autophagy in HCECs. This finding is consistent with previous reports that SiNPs can induce cellular stress38,39,40,41. The similar elevation of autophagy by SiNPs was observed in our previous reports using human corneal epithelial cells and keratocytes10,11. Autophagy is known as a natural cellular process that cleans up unnecessary and dysfunctional cellular components for recycling42. It also helps cells to overcome external stress and survive in harsh environments. Recently, it was reported that autophagy promotes the degradation of polyethyleneimine-alginate nanoparticles in endothelial progenitor cells43. Another study reported that the increased osteoblast proliferation was induced by autophagy after tantalum nanoparticle exposure44. Therefore we hypothesize autophagy system is one of the cellular mechanism to overcome SiNP-induced stress. It is noteworthy that mTOR pathway and cell viability remained intact even with increased autophagy in our study.
Unfortunately, the primary culture of HCECs has a limited proliferation capacity. Using primary cultured HCECs from different donors can cause donor-specific effects, such as age and topography-related (central vs. peripheral origin) effects on experimental results2. Therefore, because our studies required a great number of homogeneous cells, we used the HCECs cell line B4G12 in this study. This cell line is one of the two clonal lines obtained from the HCEC-12 cell line, which was made by the immortalization of parental cells from a 91-year-old woman (http://www.creative-bioarray.com/HCEC-B4G12-CSC-C3457-item-1468.htm). B4G12 can provide sufficient homogenous cell numbers for multiple experiments. As observed in many cell lines, the properties of HCECs and B4G12 are not always the same. Nevertheless, B4G12 adequately expresses HCEC-specific 9.3. E-antigen, ZO-1, and occludin45. In addition, B4G12 transplanted to replace corneal endothelium in rabbit eyes was able to successfully restore the Na+/K+ pump function and maintain corneal transparency46. B4G12 has been actively used as an ideal model for differentiated HCECs because of its morphologic and functional similarity47,48,49.
To compensate for the limitation of using immortalized B4G12 cells, we further verified the safety of SiNPs by using ex vivo human corneas and an in vivo rabbit model. We found that 50, 100, and 150 nm-sized SiNPs induced no significant endothelial toxicity in both human and rabbit corneas. The well-maintained hexagonal architecture suggests that the SiNPs did not cause significant cellular damage at the tested concentration.
Our study has several limitations. First, we tested limited sizes and concentrations of SiNPs (up to 100 µg/mL and three different sizes). A further increase in SiNP concentration to a higher range or with smaller particle sizes may possibly induce significant cellular damage in HCECs. Moreover, the uptake of SiNPs by cells may eventually lead to the chronic perturbation of intracellular mechanisms and cellular damage. Therefore, a close in vivo observation for an extended period of time (e.g., years) is necessary to further verify the safety of SiNPs. Second, the long-term exposure effects of SiNPs on HCECs are lacking. Note that ex vivo human corneal tissue culture is different from the in vivo environment because the dynamic circulation of aqueous humor is absent in a tissue culture setting.
In summary, we found SiNPs of sizes 50, 100, and 150 nm to be safe in HCECs at up to 72 h of exposure. The cellular uptake of SiNPs was localized inside the vacuoles of the cytoplasm with no nuclear membrane or mitochondrial damage. The cellular survival in the mTOR pathway remained intact, although some activation of autophagy was observed at higher concentrations of SiNPs. The cellular viability of HCECs was not affected at up to 48 h of exposure to SiNPs at the tested concentrations. The human corneal tissue culture revealed no significant toxicity of SiNPs at 100 μg/mL of concentration at up to 72 h. The in vivo rabbit model further verified the lack of toxicity of SiNPs in corneal endothelial cells.
Conclusions
Our current study verified the safety of 0, 100, 150 nm sized SiNPs in human HCECs. These findings can facilitate the future development of the SiNP-based ophthalmic drug delivery method for intractable eye diseases.
Materials and Methods
Synthesis and Characterization of Nanoparticles
Three sizes of silica (SiO2) nanoparticles (SiNPs; sizes: 50, 100, and 150 nm) were manufactured using the Stöber synthesis method as previously reported10,11. The synthesis of 50 nm of SiNPs started with mixing 2 mL of ammonia (NH4OH, 28%, Junsei, Tokyo, Japan) and 50 mL of ethyl alcohol (EtOH, anhydrous, 99.5%, Daejung, Kyeonggi, Korea) were first mixed. Then, 1 mL of tetraethyl orthosilicate (TEOS, Samchun, Gyunggi, Korea) was added. Similarly, 100 nm and 150 nm of SiNPs were prepared using equal molar ratios of ingredients. Afterward, 1.5 mL of TEOS was added to the mixture of 3 mL solution of ammonia in 50 mL of ethyl alcohol. Then, the solutions were stirred continuously for 12 h at an ambient condition (25 °C, 1 atm). Smaller-sized SiNPs could be produced by quickly adding TEOS while stirring the solution. The prepared SiNPs were washed with EtOH three times using centrifugation (10,000 rpm, 15 min). The final SiNP precipitates were dispersed in distilled water.
The surface charge of the prepared SiNPs was measured by the zeta potential (SZ-100, Horiba, Kyoto, Japan) in both distilled water and DPBS. In addition, SEM (SIGMA, Carl Zeiss, Oberkochen, Germany) images and ImageJ software were used to analyze the size and distribution of SiNPs. The dispersity of SiNPs was defined as the coefficient of variation (Dispersity (%) = \({\rm{\sigma }}/d\times 100\), where \({\rm{\sigma }}\) is the standard deviation and d is the mean size)50.
Cell Culture
The limited proliferative capability of cultured primary HCECs makes any in vitro experiment requiring large numbers of these cells unrealistic. Therefore, we used an established HCEC line (i.e., B4G12 cells) in this study. B4G12 cells (Cat no.CSC-C3457-CRA, Creative Bioarray, Shirley, NY, USA) were used. The cells were cultured in tissue culture-treated plastic at 4 × 104 cells/cm2. The culture medium recommended by the company, which contains human endothelial serum free medium (Cat no. CM-345L7, Creative Bioarray, Shirley, NY, USA) and 10 ng/ml of fibroblast growth factor-2 (Cat no. CSC-CTK0134, Creative Bioarray, Shirley, NY, USA), was used. After reaching confluency, the cells were harvested and resuspended in the culture medium. The cells were plated in 75 cm2 tissue flasks and then maintained at 37 °C in a 5% CO2 and 95% air-humidified atmosphere. The culture medium was changed every three days, and the cells were passaged using 0.25% Trypsin- ethylenediaminetetraacetic acid (EDTA) (Gibco BRL, Carlsbad, CA, USA). The passage number ≤5 was used for the study.
Treatment of SiNPs
SiNPs with sizes of 50, 100, and 150 nm were confirmed using SEM. Before being mixed into the HCECs culture medium, the stock solution of the SiNPs, which was 10 mg/mL in DPBS (Gibco), were sonicated for 30 min. HCECs were cultured in the SiNP-containing culture medium in a 5% CO2 and 95% air-humidified atmosphere at 37 °C for 24 h or 48 h.
Electron Microscopy Analysis
The intracellular distribution of SiNPs in HCECs was investigated by TEM as previously described11. The HCECs were treated with three sizes of SiNPs (100 µg/ml) for 24 h, and then the cells were fixed in 3.7% paraformaldehyde (Sigma–Aldrich, St. Louis, MO, USA) and 2.5% glutaraldehyde (Sigma–Aldrich, St. Louis, MO, USA) in a 0.1 M phosphate buffer (PB; pH7.6) overnight. After washing in 0.1 M PB, the HCECs were fixed in 1% osmium tetroxide in the same buffer for 1 h. Dehydration of cells was performed with a series of graded EtOH (Merck, Kenilworth, NJ, USA), and then the cells were embedded in an epoxy embedding medium (Sigma–Aldrich, St. Louis, MO, USA). Polymerization was then performed at 60 °C for three days. Ultrathin sections (60–70 nm) of the samples were obtained by an ultramicrotome (Leica Ultracut UCT, Leica, Germany). Obtained sections collected on grids (200 mesh) were examined under the TEM (JEM-1010; JEOL, Tokyo, Japan) operating at 60 kV. The images were recorded by a charge-coupled device camera (SC1000; Gatan, Warrendale, PA, USA). Length on the electron micrograph was measured using the GMS software (Gatan, Warrendale, PA, USA). The normal control for TEM was incubated in a corneal basal medium without SiNPs for 24 h.
LDH Assay
Necrotic cell death with plasma membrane damage was evaluated using an LDH cytotoxicity detection kit (Takara Bio Inc., Shiga, Japan)10. The experimental procedure was previously described and performed following the manufacturer’s protocol11. Briefly, HCECs were cultured at 3 × 103 cells/well in a 96-well plate and incubated for 24 h and 48 h. Following the adherence of cells, 50, 100, and 150 nm SiNPs were applied to the cells for 48 h dose dependently at 0, 25, 50, and 100 µg/ml. The wells with no SiNP addition and the wells with 1% triton X-100 addition were used as the negative and positive controls, respectively. Following the incubation of cells, cell free supernatants were transferred into a new 96-well plate. The wells were incubated with the reaction mixture for 20 min at room temperature (RT). Absorbance at 490 nm was measured.
Cell Viability Assay
A commercial cell counting kit (CCK-8; Dojindo Molecular Technologies, Inc., Kumamoto, Japan) was used to measure HCECs’s viability according to the manufacturer’s protocol11. Briefly, the HCECs were cultured at 3 × 103 cells/well in a 96-well plate and incubated for 24 h. Following the adherence of cells, 50, 100, and 150 nm SiNPs were added to the culture media for 24 h and 48 h over a range of concentrations (0, 25, 50, and 100 µg/ml). After the appropriate incubation, 10 µL of CCK-8 solution was added to each cultured well, and absorbance at 450 nm was determined after 2 h of incubation of the HCECs with the reagent at 37 °C.
Western Blot Analysis
Western blot analysis was performed following the previously reported method11. All SiNP-treated HCECs were lysed in an ice-cold radioimmunoprecipitation assay buffer [50 mM Tris-HCl (pH 8.0), 150 mM NaCl, 1% NP-40, 0.5% deoxycholate, and 0.1% sodium dodecyl sulfate (SDS)] for 30 min. Debris was removed by centrifugation at 16,000 g for 1 min. Equal amounts (20 μg) of total cell protein were separated by SDS–polyacrylamide gel electrophoresis and transferred to a polyvinylidene difuoride membrane. After blocking with 5% bovine serum albumin (BSA) in tris buffered saline with tween 20 (10 mM Tris, pH 8.0, 150 mM NaCl, 0.1% Tween 20) for 1 h at RT, the membranes were incubated overnight at 4 °C with the following primary antibodies: rabbit anti-phospho-mTOR (1:1000; catalog number: 5536; Cell Signaling), rabbit anti-mTOR (1:1000; catalog number: 2983; Cell Signaling), rabbit anti-LC3A/B (1:1000; catalog number: 12741; Cell Signaling, Beverly, MA, USA), and mouse anti-β-actin (1:10,000; catalog number: sc-47778; Santa Cruz, Biotechnology, Dallas, Texas, USA). Then, incubation with peroxidase-conjugated secondary antibody was performed for 1 h at RT. Blots were developed using an enhanced chemiluminescence kit (catalog number: RPN2232; GE healthcare, Buckinghamshire, UK) and visualized using a Fujifilm Image Reader LAS-3000 (Fujifilm, Tokyo, Japan). Densitometric analysis was performed using Multi Gauge V3.0 (Fujifilm Life Science, Tokyo, Japan). Each experiment was repeated at least as triplicate.
Immunocytochemistry
As previously reported11, the HCECs were seeded at a density of 2 × 104 cells per milliliter and grown on 4-well Lab-Tek chamber slides (Nalgene Nunc International, Penfield, NY, USA), and 100 µg/mL of 50, 100, 150 nm-sized SiNPs was treated for 24 h. The HCECs were fixed with 3.7% paraformaldehyde for 10 min at RT, and permeabilization was performed using 0.1% triton x-100 for 5 min at RT11. After washing with DPBS, the blocking of non-specific antigen site was done using 1% BSA in DPBS for 30 min at RT. The chamber slides were incubated at 4 °C overnight with rabbit polyclonal anti-LC3B (0.5 ug/mL; catalog number: L10382; Molecular Probes, ThermoFisher Scientific Inc., Waltham, MA, USA). Next, the slides were washed with DPBS and incubated with Alexa 488-conjugated donkey anti-rabbit antibody (1:1000; catalog number: A21206; Molecular Probes) for 2 h at RT. Tetramethylrhodamine isothiocyanate (TRITC)-conjugated phalloidin (1 µg/mL; Sigma–Aldrich, St. Louis, MO, USA) was used for staining of F-actin. Nuclear counterstaining was performed using 4′,6-diamidino-2′-phenylindole (DAPI, catalog number: P36931; Molecular Probes) with a mounting solution. Finally, slides were examined under a fluorescence microscope.
Ex Vivo HCEC Toxicity Assay
Untransplantable human corneal donor buttons (“research use only” grade) were provided by Eversight International (Seoul, South Korea). Two corneas were from a 63-year-old male donor and another two corneas were from a 59-year-old male donor. Informed consent regarding the possible research use of the corneas was obtained from the donors when they agreed on tissue donation form. The experiment followed the tenets of the Declaration of Helsinki and was approved by the institutional review board of Dongguk University, Ilsan Hospital, Goyang, South Korea. The corneas were harvested at the date of death of the donors and used for the experiment at 9 and 11 days after death. Fresh human corneal donor buttons (n = 4) were divided by quadrant segments. Each segment was stained with 0.005% trypan blue mixed with minimum essential medium (MEM) for 5 min. Corneal endothelial cell viability was assessed by examining the blue-stained area under an inverted-phase contrast microscope. After the baseline viability assessment, the corneal segments were divided into four groups (n = 4 in each group), and each segment was incubated at 37 °C in a 5% CO2 and 95% air-humidified atmosphere for 72 h. The tissue culture medium was serum-free MEM containing L-glutamine (2 mM), NaHCO3 (20 g/L), penicillin (100 IE/mL), and streptomycin (0.1 mg/mL). Three different sizes (50, 100, and 150 nm) of SiNPs were mixed in the tissue culture medium at a 100 µg /mL concentration (n = 4 each group). The tissue culture medium with no SiNPs was used for the control group (n = 4). After 72 h of incubation with SiNPs, the corneal segments were stained again with 0.005% trypan blue mixed with MEM for 5 min. Any increase in the blue-stained area from the baseline was used as the indicator of corneal endothelial cell toxicity, and these were compared among the groups. After trypan blue evaluation, the corneal segments (n = 3 each group) were fixed in 10% formalin and incubated with TRITC-conjugated phalloidin (1 µg/mL; Sigma–Aldrich). The tissue was rinsed three times with PBS (5 min per rinse), and the whole-mount corneas were mounted endothelial-side down on a slide and stained with DAPI (catalog number: P36931; Molecular Probes). The slides were examined with a fluorescent microscope.
In Vivo Rabbit Corneal Endothelial Cell Toxicity Assay
To investigate the in vivo corneal effect of SiNPs, we used 12 New Zealand white rabbits (males, weighing 2.5–3.0 kg). The animals were treated in compliance with the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research. Experimental protocol was approved by Institutional Animal Care and Use Committee of Dongguk University, Ilsan Hospital (reference number: 2016–03146). The rabbits were divided into four groups (n = 3, each group), including the negative control group, and treated with intracameral injection of the SiNP solution (0.05 ml) of each size of SiNP (50, 100, 150 nm-sized SiNPs, 200 μg/mL concentration mixed with balanced salt solution) to the right eyes. To consider the average aqueous humor volume of rabbits (290 μL), the final concentration of SiNP in the anterior chamber was estimated as 30 μg/mL. The left eyes were used for the negative control. Corneal photographs of both eyes were taken at baseline, days 1, 2, and 3, and weeks 1 and 2. Corneal transparency was evaluated according to these photographs. At two weeks after the intracameral injection, the rabbits were euthanized and both eyes were enucleated. Tissues were fixed in 10% formalin, and a histopathologic examination using hematoxylin and eosin staining was performed. One cornea from each group was incubated with TRITC-conjugated phalloidin (1 µg/mL; Sigma–Aldrich). The tissue was rinsed three times with PBS (5 min per rinse), and the whole-mount corneas were mounted endothelial-side down on a slide and stained with DAPI (catalog number: P36931; Molecular Probes). The slides were examined with a fluorescent microscope. Using the fluorescent pictures, endothelial cell count (DAPI stained nucleus) in three 500 μm × 500 μm square areas was calculated in each cornea using ImageJ software (http://imagej.nih.gov/ij/).
Statistical Analysis
Data were presented as mean ± standard error, and statistical significance was determined by ANOVA and Dunnett’s multiple comparison test. P values of less than 0.05 were regarded as significant by GraphPad Prism Ver. 5.01 (GraphPad Software Inc., La Jolla, CA, USA).
References
Eghrari, A. O., Riazuddin, S. A. & Gottsch, J. D. Overview of the Cornea: Structure, Function, and Development. Progress in molecular biology and translational science 134, 7–23 (2015).
Joyce, N. C. Proliferative capacity of corneal endothelial cells. Experimental eye research 95, 16–23 (2012).
Napierska, D., Thomassen, L. C., Lison, D., Martens, J. A. & Hoet, P. H. The nanosilica hazard: another variable entity. Particle and fibre toxicology 7, 39 (2010).
Kong, M. et al. Biodegradable Hollow Mesoporous Silica Nanoparticles for Regulating Tumor Microenvironment and Enhancing Antitumor Efficiency. Theranostics 7, 3276–3292 (2017).
Huang, P. et al. Molecularly organic/inorganic hybrid hollow mesoporous organosilica nanocapsules with tumor-specific biodegradability and enhanced chemotherapeutic functionality. Biomaterials 125, 23–37 (2017).
Mohammadpour, M., Jabbarvand, M., Hashemi, H. & Delrish, E. Prophylactic effect of topical silica nanoparticles as a novel antineovascularization agent for inhibiting corneal neovascularization following chemical burn. Advanced biomedical research 4, 124 (2015).
Mun, E. A., Morrison, P. W., Williams, A. C. & Khutoryanskiy, V. V. On the barrier properties of the cornea: a microscopy study of the penetration of fluorescently labeled nanoparticles, polymers, and sodium fluorescein. Molecular pharmaceutics 11, 3556–3564 (2014).
Napierska, D. et al. Size-dependent cytotoxicity of monodisperse silica nanoparticles in human endothelial cells. Small 5, 846–853 (2009).
Kim, I. Y., Joachim, E., Choi, H. & Kim, K. Toxicity of silica nanoparticles depends on size, dose, and cell type. Nanomedicine: nanotechnology, biology, and medicine 11, 1407–1416 (2015).
Yim, B. et al. The Effects of Nonporous Silica Nanoparticles on Cultured Human Keratocytes. Investigative ophthalmology & visual science 58, 362–371 (2017).
Park, J. H. et al. The Effect of Silica Nanoparticles on Human Corneal Epithelial Cells. Scientific reports 6, 37762 (2016).
Nieto, A., Hou, H., Sailor, M. J., Freeman, W. R. & Cheng, L. Ocular silicon distribution and clearance following intravitreal injection of porous silicon microparticles. Experimental eye research 116, 161–168 (2013).
van Dooren, B. T., Beekhuis, W. H. & Pels, E. Biocompatibility of trypan blue with human corneal cells. Archives of ophthalmology 122, 736–742 (2004).
Verma, P. & Ahuja, M. Cubic liquid crystalline nanoparticles: optimization and evaluation for ocular delivery of tropicamide. Drug delivery 1–12 (2016).
Taketani, Y. et al. Topical Use of Angiopoietin-like Protein 2 RNAi-loaded Lipid Nanoparticles Suppresses Corneal Neovasculari-zation. Molecular therapy. Nucleic acids 5, e292 (2016).
Tandon, A. et al. BMP7 gene transfer via gold nanoparticles into stroma inhibits corneal fibrosis in vivo. PloS one 8, e66434 (2013).
Jani, P. D. et al. Nanoparticles sustain expression of Flt intraceptors in the cornea and inhibit injury-induced corneal angiogenesis. Investigative ophthalmology & visual science 48, 2030–2036 (2007).
Contreras-Ruiz, L. et al. Ocular tolerance to a topical formulation of hyaluronic acid and chitosan-based nanoparticles. Cornea 29, 550–558 (2010).
Jumelle, C. et al. Delivery of macromolecules into the endothelium of whole ex vivo human cornea by femtosecond laser-activated carbon nanoparticles. The British journal of ophthalmology (2016).
Yang, J. et al. Potential of CeCl3@mSiO2 nanoparticles in alleviating diabetic cataract development and progression. Nanomedicine: nanotechnology, biology, and medicine (2017).
Maulvi, F. A. et al. Extended release of ketotifen from silica shell nanoparticle-laden hydrogel contact lenses: in vitro and in vivo evaluation. Journal of materials science. Materials in medicine 27, 113 (2016).
Molokhia, S. A., Thomas, S. C., Garff, K. J., Mandell, K. J. & Wirostko, B. M. Anterior eye segment drug delivery systems: current treatments and future challenges. Journal of ocular pharmacology and therapeutics: the official journal of the Association for Ocular Pharmacology and Therapeutics 29, 92–105 (2013).
Brown, T. Silica exposure, smoking, silicosis and lung cancer–complex interactions. Occupational medicine 59, 89–95 (2009).
Finkelstein, M. M. Silica, silicosis, and lung cancer. Journal of occupational and environmental medicine / American College of Occupational and Environmental Medicine 43, 198–201 (2001).
Tamba, B. I. et al. Silica nanoparticles: preparation, characterization and in vitro/in vivo biodistribution studies. European journal of pharmaceutical sciences: official journal of the European Federation for Pharmaceutical Sciences 71, 46–55 (2015).
Kim, Y. R. et al. Toxicity of colloidal silica nanoparticles administered orally for 90 days in rats. International journal of nanomedicine 9(Suppl 2), 67–78 (2014).
Ryu, H. J. et al. Evaluation of silica nanoparticle toxicity after topical exposure for 90 days. International journal of nanomedicine 9(Suppl 2), 127–136 (2014).
Croissant, J.G., Fatieiev, Y. & Khashab, N.M. Degradability and Clearance of Silicon, Organosilica, Silsesquioxane, Silica Mixed Oxide, and Mesoporous Silica Nanoparticles. Advanced materials 29 (2017).
Zhai, W. et al. Degradation of hollow mesoporous silica nanoparticles in human umbilical vein endothelial cells. Journal of biomedical materials research. Part B, Applied biomaterials 100, 1397–1403 (2012).
Chen, G., Teng, Z., Su, X., Liu, Y. & Lu, G. Unique Biological Degradation Behavior of Stober Mesoporous Silica Nanoparticles from Their Interiors to Their Exteriors. Journal of biomedical nanotechnology 11, 722–729 (2015).
Nemmar, A. et al. Oxidative stress, inflammation, and DNA damage in multiple organs of mice acutely exposed to amorphous silica nanoparticles. International journal of nanomedicine 11, 919–928 (2016).
Zhuravskii, S. et al. Mast cell accumulation precedes tissue fibrosis induced by intravenously administered amorphous silica nanoparticles. Toxicology mechanisms and methods 26, 260–269 (2016).
Lin, W., Huang, Y. W., Zhou, X. D. & Ma, Y. In vitro toxicity of silica nanoparticles in human lung cancer cells. Toxicology and applied pharmacology 217, 252–259 (2006).
Xu, Y. et al. Exposure to silica nanoparticles causes reversible damage of the spermatogenic process in mice. PloS one 9, e101572 (2014).
Han, H. et al. Toxic and adjuvant effects of silica nanoparticles on ovalbumin-induced allergic airway inflammation in mice. Respiratory research 17, 60 (2016).
Blechinger, J. et al. Uptake kinetics and nanotoxicity of silica nanoparticles are cell type dependent. Small 9, 3970–3980, 3906 (2013).
Jo, D. H., Kim, J. H., Yu, Y. S., Lee, T. G. & Kim, J. H. Antiangiogenic effect of silicate nanoparticle on retinal neovascularization induced by vascular endothelial growth factor. Nanomedicine: nanotechnology, biology, and medicine 8, 784–791 (2012).
Mendoza, A. et al. Silica nanoparticles induce oxidative stress and inflammation of human peripheral blood mononuclear cells. Cell stress & chaperones 19, 777–790 (2014).
Petrache Voicu, S. N. et al. Silica Nanoparticles Induce Oxidative Stress and Autophagy but Not Apoptosis in the MRC-5 Cell Line. International journal of molecular sciences 16, 29398–29416 (2015).
Guo, C. et al. Silica nanoparticles induce oxidative stress, inflammation, and endothelial dysfunction in vitro via activation of the MAPK/Nrf2 pathway and nuclear factor-kappaB signaling. International journal of nanomedicine 10, 1463–1477 (2015).
Ye, Y. et al. Nano-SiO2 induces apoptosis via activation of p53 and Bax mediated by oxidative stress in human hepatic cell line. Toxicology in vitro: an international journal published in association with BIBRA 24, 751–758 (2010).
Shintani, T. & Klionsky, D. J. Autophagy in health and disease: a double-edged sword. Science 306, 990–995 (2004).
Wang, G. D., Tan, Y. Z., Wang, H. J. & Zhou, P. Autophagy promotes degradation of polyethyleneimine-alginate nanoparticles in endothelial progenitor cells. International journal of nanomedicine 12, 6661–6675 (2017).
Kang, C. et al. Involvement of autophagy in tantalum nanoparticle-induced osteoblast proliferation. International journal of nanomedicine 12, 4323–4333 (2017).
Valtink, M., Gruschwitz, R., Funk, R. H. & Engelmann, K. Two clonal cell lines of immortalized human corneal endothelial cells show either differentiated or precursor cell characteristics. Cells, tissues, organs 187, 286–294 (2008).
Ju, C., Gao, L., Wu, X. & Pang, K. A human corneal endothelium equivalent constructed with acellular porcine corneal matrix. The Indian journal of medical research 135, 887–894 (2012).
Sornelli, F., Lambiase, A., Mantelli, F. & Aloe, L. NGF and NGF-receptor expression of cultured immortalized human corneal endothelial cells. Molecular vision 16, 1439–1447 (2010).
Hsueh, Y. J. et al. Lysophosphatidic acid induces YAP-promoted proliferation of human corneal endothelial cells via PI3K and ROCK pathways. Molecular therapy. Methods & clinical development 2, 15014 (2015).
Levis, H. J. et al. Plastic compressed collagen as a novel carrier for expanded human corneal endothelial cells for transplantation. PloS one 7, e50993 (2012).
Baalousha, M. & Lead, J. R. Nanoparticle dispersity in toxicology. Nature nanotechnology 8, 308–309 (2013).
Acknowledgements
The authors would like to thank David Lee and Erik Hellier at Eversight International (Seoul, South Korea) for their generous supply of human donor cornea tissues for this research. The publication of this article was supported by a grant of the Korea Health Technology R&D Project through the Korea Health Industry Development Institute funded by the Ministry of Health & Welfare, Republic of Korea (Grant number: HI-15C1653).
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J.Y.K., J.H.P., R.S.C., C.Y.P. designed the experiment, M.K., J.Y.K., C.Y.P. wrote the main manuscript text, H.J., J.H. prepared Fig. 1 and Table 1, J.P., H.J., J.Y.K. prepared Figs 2–6, J.H.P., J.Y.K., M.K. prepared Figs 7, 8, J.P., R.S.C., C.Y.P. corrected and proof read the manuscript. All authors reviewed the manuscript.
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Kim, JY., Park, JH., Kim, M. et al. Safety of Nonporous Silica Nanoparticles in Human Corneal Endothelial Cells. Sci Rep 7, 14566 (2017). https://doi.org/10.1038/s41598-017-15247-2
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DOI: https://doi.org/10.1038/s41598-017-15247-2
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