In phacoemulsification, ultrasound induces hydroxyl radical (·OH) formation, damaging corneal endothelium. Whether H2 can prevent such oxidative damage in phacoemulsification was examined by in vitro and in vivo studies. H2 was dissolved in a commercial irrigating solution. The effects of H2 against ·OH generation were first confirmed in vitro by electron-spin resonance (ESR) and hydroxyphenyl fluorescein (HPF). ESR showed a significantly decreased signal magnitude and fluorescence intensity by oxidized HPF was significantly less in the H2-dissolved solution. The effects of H2 in phacoemulsification were evaluated in rabbits, comparing H2-dissolved and control solutions. Five hours after the procedure, the whole cornea was excised and subjected to image analysis for corneal edema, real-time semiquantitative PCR (qPCR) for heme oxygenase (HO)-1, catalase (CAT), superoxide dismutase 1 (SOD1) and SOD2 mRNA and immunohistochemistry. Corneal edema was significantly less and the increases in anti-oxidative HO-1, CAT and SOD2 mRNA expressions were significantly suppressed in the H2 group. In addition, corneal endothelial cell expressions of two oxidative stress markers, 4-HNE and 8-OHdG, were significantly lower in the H2 group. In conclusion, H2 dissolved in the ocular irrigating solution protected corneal endothelial cells from phacoemulsification-induced oxidative stress and damage.
Most cataract surgeries are today performed by phacoemulsification, which uses high-intensity ultrasound (US) energy for fragmentation and emulsification of the lens. With the progress in surgical devices and the development of techniques, indications for phacoemulsification have now expanded to include mature cataract in which the lens nucleus is hard, so that greater US energy for emulsification is needed. Since human corneal endothelial cells lack mitotic activity in vivo, excessive damage to the tissue can cause significant decreases in endothelial cell density. Corneal endothelium maintains hydration of the corneal tissues by acting as a barrier and a draining pump against the aqueous humor; thus, decreases in endothelial cell density can induce irreversible corneal edema (bullous keratopathy; BK), in turn causing permanently blurred vision and pain. With an excessive amount of US energy1,2, collision of lens nucleus fragments with the corneal endothelium3, air bubbles4,5, or a localized temperature rise6,7,8 have been reported and are well known as factors damaging to the corneal endothelium. The development of free radicals has also been identified as a harmful factor associated with the use of US. Considering the oxidative insult to endothelial cells caused by free radicals, their presence in the anterior chamber may represent one of the most damaging factors during these procedures.
In the fields of physics and engineering, high-intensity US oscillating in an aqueous solution is well known to induce free radicals9. The cause is acoustic cavitation, a phenomenon whereby gas bubbles develop due to ebullism or evaporation and grow under negative pressure and they then collapse under positive pressure as a result of pressure fluctuations caused by US. When bubbles collapse, they generate shock waves that induce localized high pressures of >600 atmospheres and temperature elevations of >5000 K. The energy created extends to neighboring water molecules, causing direct disintegration. This phenomenon (H2O→·OH +·H) is called sonolysis and the ·OH, i.e. hydroxyl radical, is the most reactive of the various reactive oxygen species (ROS), including superoxide anion, singlet-dioxygen and hydrogen peroxide. The production of ·OH by an ophthalmic phacoemulsificator was first reported by Cameron et al.10. They detected ·OH using electron spin resonance (ESR) in a closed circuit and demonstrated that ·OH production was proportional to the US oscillation time. We then also demonstrated ·OH production by ESR in the anterior chamber of a model eye under clinical conditions of phacoemulsification11. In addition, we proved that free radicals produced by phacoemulsification were the cause of corneal endothelial damage using 8-hydroxy-2-deoxyguanosine (8-OHdG) as an oxidative stress marker in animal eyes12.
To maintain the anterior chamber of the eye and to protect the corneal endothelium from various forms of surgical damage during phacoemulsification, an ophthalmic viscosurgical device (OVD) is injected into the anterior chamber before phacoemulsification as a standard procedure. The major ingredient of an OVD is sodium hyaluronate (HA), which is a known free radical scavenger. The protective properties of HA against oxidative stress in the corneal endothelium have been reported13 and we also demonstrated the scavenging effect of OVD against ·OH in a model eye study11,14. The effect of the material, however, depends on its retention in the anterior chamber during phacoemulsification11,14, because the material can be aspirated and disappear in the process of surgery. A new method of constant protection from oxidative insults during surgery has been awaited.
One promising candidate for this purpose is the hydrogen molecule, H2. In 2007, we reported that H2 selectively reduced cytotoxic ROS, ·OH, in particular, in vitro and exerted a therapeutic antioxidant activity in an ischemia-reperfusion injury model15. Since then, the effect of H2 against oxidative stress-induced injury in several organs, including the brain, heart, lung, intestine, or bone marrow, has been reported16,17,18,19. In the field of ophthalmology, we reported that H2 was effective to prevent ischemia reperfusion injury in the retina in a retinal artery occlusion model20. Considering the effect of H2 against ·OH, H2 dissolved in ocular irrigating solutions should work as a free radical scavenger in the anterior chamber. In this study, we examined the effect of H2 in phacoemulsification. We have demonstrated that US in phacoemulsification induces ·OH, which damages corneal endothelium11,12. If H2 dissolved in ocular irrigating solutions could prevent oxidative damage to the corneal endothelium, it would have great clinical usefulness.
H2 concentration in the solution
To prepare the H2-dissolved ocular irrigating solution, bags containing the solution were placed in H2 gas. After 24-hour and 1-week exposure of the solution to 100% H2 gas in an acrylic chamber (Fig. 1a), the dissolved concentration of H2 in the solution was 61.9% and 61.8%, respectively, indicating that H2 gas easily penetrated through a plastic bag and that the solution was almost equilibrated with H2 gas in the chamber within 24 hours. Thus, the H2-dissolved irrigating solution after 24-hour exposure was used for the following experiments. The H2 concentration in the anterior chamber of the porcine eye (Fig. 1b) under continuous irrigation (10 ml/min) with the H2-dissolved solution for 30 minutes showed little change, from 56.5% to 53.7% (Fig. 1c). To confirm O2 supply to the tissue, the O2 concentration was also measured. At 2 minutes of irrigation with the H2-dissolved solution, the O2 concentration in the anterior chamber was 5.4% ± 0.6%.
Detection of ·OH by ESR and by HPF
To demonstrate the reduction of ·OH with dissolved H2, ocular irrigating solutions containing DMPO were treated with the US device. Their ESR spin adducts showed the characteristic quartet signal pattern of DMPO-OH. The signal magnitude in the H2-dissolved solution was apparently suppressed (Fig. 2a). When the intensities of the signals were calculated by image analysis after standardization using the amplitudes of the Mn signal, the difference was significant (Fig. 2b; control 100 ± 30.8, H2 group 60.5 ± 7.8, p < 0.05). Similarly, ocular irrigating solutions containing HPF were treated with the US device. Their fluorescence intensity by oxidized HPF was significantly smaller in the H2-dissolved solution than in the control (Fig. 2c; Control 3588 ± 210.0, H2 group 1032.5 ± 324.7, p < 0.005).
Image analysis of corneal edema
Figure 3a (control) and b (H2 group) shows the US probe position in the anterior chamber of the rabbit when US oscillation was performed. The representative photographs of the anterior segment at 5 hours after US exposure are shown in Fig. 3c (control) and d (H2 group). The opaque, i.e. edematous lesion, was less apparent in the H2 group eye than in the control eye. To compare the amplitude of the edema quantitatively, the intensity of the opaque lesion was analyzed using ImageJ software. Representative images of the excised corneas in the control and the H2 groups are shown in Fig. 3e,f, respectively. The average index of the intensity was significantly smaller in the H2 group (5.6 ± 8) than in the control (47.8 ± 15.2) (Fig. 3g; p < 0.005).
HO-1, CAT, SOD1 and SOD2 mRNA in corneal endothelial cells
At 5 hours after US exposure, the cornea was excised and total RNA was extracted from the corneal endothelial cells. Real-time qPCR analysis of anti-oxidative heme oxygenase (HO)-1, catalase (CAT), superoxide dismutase 1 (SOD1) and SOD2 mRNAs showed that US exposure increased expressions of HO-1, CAT and SOD2 in the corneal endothelium (Fig. 4a–d). The increase in HO-1 mRNA was significantly suppressed in the H2 group compared to the control (28.5 fold ± 15.0 vs. 66.4 fold ± 22.3, p < 0.005) (Fig. 4a). The increases in CAT and SOD2 mRNAs were also significantly suppressed in the H2 group compared to the control (0.42 fold ± 0.28 vs. 1.56 fold ± 0.88, p < 0.005 and 1.38 fold ± 0.38 vs. 1.92 fold ± 0.36, p < 0.01), respectively (Fig. 4b,d).
The expressions of two oxidative stress markers, 4-HNE and 8-OHdG, in the corneal endothelial cells at 5 hours after US exposure are shown in Fig. 5a–d, respectively. The number of 4-HNE-positive cells decreased in the H2 group (143.7 ± 124.6 cells/cornea) compared to the control (1586 ± 1315.6 cells/cornea, p < 0.05) (Fig. 5e). Furthermore, 8-OHdG-positive cells decreased in the H2 group (330.8 ± 730.9 cells/cornea) compared to the control (2518.7 ± 2294 cells/cornea, p < 0.05) (Fig. 5f).
Corneal endothelial damage induces corneal edema and when the damage is excessive, it results in irreversible bullous keratopathy (BK). Because the corneal endothelial cells lack the ability to regenerate, transplantation of corneal tissue is the only cure currently available. A recent national survey on BK in Japan showed that cataract surgery was the most common cause of penetrating keratoplasty (24.2%)21 and a more recent study in the UK showed that, among the indications for endothelial keratoplasty, cataract surgery ranked second following Fuchs’ endothelial dystrophy22. Furthermore, corneal endothelial damage in a limited area, if it does not result in irreversible BK, is one of the most frequent complications after phacoemulsification and can cause temporary visual dysfunction in many post-phacoemulsification patients. Even though the safety of phacoemulsification has been dramatically improved due to progress in the apparatus and development of surgical devices including OVDs, the prevention of corneal endothelial damage in phacoemulsification is still an important issue for cataract surgeons.
The effect of H2 as a free radical scavenger has been vigorously investigated in various conditions in vitro or in vivo23, since our report first described its effect15. We first showed that H2 dose-dependently reduces ·OH in vitro, whereas H2 is too weak to reduce physiologically important ROS such as NO· and superoxide. H2, the smallest molecule in the universe, has the unique ability of rapidly diffusing across membranes; it can react with cytotoxic ·OH in all organelles, including mitochondria and the nucleus and thus effectively protects cells against oxidative damage. Indeed, H2 prevented a decrease in the cellular levels of ATP synthesized in mitochondria15.
In phacoemulsification, ·OH production by US has been demonstrated10,11 and corneal endothelial damage by oxidative insults has also been demonstrated12. Considering the effect of H2 and the consequence of sonolysis in phacoemulsification, it seemed reasonable and worthwhile to investigate the usefulness of H2 dissolved in the irrigating solution, because, by this method, a potent free radical scavenger can be continuously provided during the surgery.
In the current study, the H2 concentration in the irrigating solution was examined first. H2 was dissolved into solution by placing the bag into a chamber of 100% H2. H2 spontaneously penetrates through the plastic film of the bag, even without positive pressure in the chamber. This was possible because the solution, Ope Guard® neo kit, is a soft plastic product, which is why this solution was used. The H2 concentrations in the 24-hour and 1-week exposure solutions were almost the same, indicating H2 was almost saturated in the solution by 24-hour exposure with this method. Although this method has the advantage of eliminating concern about contamination, the H2 concentration in the bag decreased gradually after it was retrieved from the chamber, because H2 can escape from the bag. To confirm its validity in clinical use, H2 concentration was measured under clinical conditions. At 30 minutes of continuous irrigation, the H2 concentration in the anterior chamber was still 53.7%, suggesting that sufficient H2 concentration can be maintained during a standard phacoemulsification time (Fig. 1). Furthermore, the O2 concentration in the anterior chamber (5.4%) was confirmed to be within a safe range considering the short surgery time and the reported O2 concentration in the aqueous humor in the human eye24.
The effects of H2 in ·OH production caused by US were then examined in in vitro experiments using ESR and HPF analysis. US oscillation in the tube was performed as in our previous report11. Results of both analyses clearly demonstrated that H2 suppressed ·OH production (Fig. 2). Next, phacoemulsification simulation was performed in animal eyes to observe the effect of H2 in an in vivo model. In the procedure, the lens was not touched to avoid the effect of lens fragments on corneal endothelial damage. The difference between the H2 group and the control group was obvious. The area of the edematous lesion of the cornea evaluated by image analysis was significantly smaller in the H2 group (Fig. 3), suggesting that H2 protected the corneal endothelium from oxidative insults. To observe the physiological reaction to free radicals in the corneal endothelial cells, the expression of HO-1 mRNA was then examined in the cells after US exposure. HO-1 removes the pro-oxidant molecule heme and generates free radical scavengers, biliverdin and bilirubin; therefore, HO-1 is usually regarded as an antioxidant-inducible cellular defense protein and an increase of HO-1 mRNA indicates that oxidative stress occurred in the cells25. The mRNA expressions of other anti-oxidative enzymes, including CAT, SOD1 and SOD2 were also examined and all of them were suppressed in the H2 group, with significant changes in CAT and SOD2. Suppression of US exposure-induced HO-1, CAT and SOD2 mRNA expressions in the H2 group (Fig. 4a,b,d) indicates that the corneal endothelial cells were protected by H2 from oxidative insults in phacoemulsification. Lastly, immunohistochemistry showed that the number of 4-HNE and 8-OHDG-positive cells was significantly smaller in the H2 group (Fig. 5), proving histologically that the oxidative damage was truly suppressed by H2.
All evidence presented in the current study strongly supports the usefulness of H2 in phacoemulsification. Among the various H2 applications in medicine reported so far, H2 dissolved in the ocular irrigating solution may be one of the most reasonable and promising uses of H2. In this system, H2 is continuously provided to the anterior chamber of the eye where ·OH is produced by US oscillation without any additional intervention such as injection or inhalation. The effect of H2 against ROS has been reported in various ways in previous studies23. Among these, although the effect in an ischemia-reperfusion injury mode has been regarded as the representative study since our first report15,20,26,27, we have also reported the effect of H2 in an irradiation-induced lung damage model19. One of the harmful effects of ionizing radiation, i.e. the indirect action, occurs when ionizing radiation interacts with water molecules in cells, which leads to production of ROS including ·OH. The ROS reacts rapidly with cellular macromolecules to damage DNA, lipids and proteins and exert strong cytotoxic effects. It has been estimated that ·OH causes 60–70% of ionizing radiation-induced cell damage28. The sonolysis-induced ·OH in phacoemulsification is another mode of oxidative insult to the cells and it seemed similar, at least partially, to irradiation-induced damage.
The standard composition of the ocular irrigating solution includes glutathione, which is a known anti-oxidative agent29,30. Although the solution, Ope Guard® neo kit, used in the current study contains glutathione, production of ·OH shown by ESR and HPF was evident. However, the results of in vivo experiments clearly showed more corneal endothelial damage in the control than in the H2 group, suggesting that glutathione alone is not enough to protect cells from oxidative stresses caused by US oscillation in this model. In addition, several reports have shown the effect of ascorbic acid as an anti-oxidative agent in an in vivo phacoemulsification model31,32 and in an in vitro model33, but no clinical trial of ascorbic acid use in phacoemulsification has yet been done. This may be because ascorbic acid can be easily oxidized to dehydroascorbic acid, which can have an effect on glutathione33. In this regard, there is no concern about oxidative adducts with H2 use. Moreover, because there is literally no barrier to H2, it can function either outside or inside the cell membrane by rapid diffusion.
In conclusion, H2 dissolved in the ocular irrigating solution effectively protected corneal endothelial cells from oxidative stress and damage caused by phacoemulsification. H2 dissolved in the irrigating solution can have a dual action: as a direct scavenger against ·OH produced by sonolysis and as an anti-oxidative agent in the cell. In the current study, the former was clearly proven by the ESR and HPF analyses. In in vivo experiments, the favorable effect of H2 was evident, but to prove the anti-oxidative function of H2 in cells clearly, further investigation is needed.
Nine-week-old, male, Japanese white rabbits, weighing 2.5 to 3.0 kg, were purchased from Tokyo Laboratory Animals Science Co. Ltd. (Tokyo, Japan). The animals were kept individually under standardized laboratory conditions and given tap water and food ad libitum. All animals were treated in accordance with the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research. Porcine eyes that were used for H2 concentration measurements were obtained from a local abattoir.
Preparation of H2-dissolved irrigating solution
The ocular irrigating solution is used to maintain the anatomic and physiologic integrity of intraocular tissues in ocular surgeries including phacoemulsification. The standard composition of commercially available irrigating solutions includes glutathione, glucose and sodium bicarbonate, which has been proven to be effective for maintenance of normal corneal endothelial functions29. In the current study, Ope Guard® neo kit (Senju Pharmaceutical, Osaka, Japan), which contains the standard ingredients, was used. Ope Guard® neo kit is a soft plastic bag product and one of the most popular irrigating solutions in Japan. To dissolve H2 in the solution, the bag was placed in an acrylic vacuum chamber (SNS-type, Sanplatec, Osaka, Japan), of which the air was replaced by 100% H2 gas (Fig. 1a). Because of its molecular size, H2 penetrates spontaneously through the plastic film of the bag even without positive pressure in the chamber. The bag was retrieved from the chamber after 24-hour or 1-week exposure and the dissolved H2 concentration in the solution was immediately measured using a needle-type H2 sensor (Unisense, Aarhus N, Denmark). Then, to assess H2 concentration changes in the anterior chamber with irrigation of H2-dissolved solution, enucleated porcine eyes were used. The H2 sensor was inserted through the incision of an enucleated porcine eye and H2 concentration was measured every 5 minutes for 30 minutes under continuous irrigation of the solution at 10 ml/min (Fig. 1b). Furthermore, to confirm O2 supply to the tissue, O2 concentration in the anterior chamber of an enucleated porcine eye at 2 minutes after the irrigation started was also measured using a needle-type O2 sensor (Unisense).
Detection of ·OH by ESR
The ·OH detection by ESR was performed similarly to our previous paper11. For spin trapping, 10% aqueous solution of 5, 5′-dimethyl-1-pyrroline N-oxide (DMPO; Labotec, Tokyo, Japan) was used. DMPO was added to the Ope Guard® neo kit solution at a final concentration of 1%. In 50-ml plastic test tubes, 10 ml of 1% DMPO/H2-dissolved solution (H2 group) or normal solution (control) was prepared. The US probe of a commercially available phacoemulsification device (Stellaris®, Bausch & Lomb, Rochester, NY) was placed in the center of the tube and US was produced at a power level of 30% for 10 seconds without irrigation and aspiration. Immediately after US, 300 μl of the solution were transferred to a flat quartz ESR cuvette. The cuvette was then placed in an ESR spectrometer (model JES-RE3X; JEOL, Tokyo, Japan) and the signals of the spin adducts, DMPO-OH, were measured by double integration wave height using a computer software program (ES-IPEITS data system version 7.0; JEOL). All measurements were performed 3 times.
Detection of ·OH by HPF
HPF is a novel reagent that directly detects certain highly reactive oxygen species (hROS)34. Although HPF itself has little fluorescence, it selectively and dose-dependently reacts with hROS, such as ·OH and peroxynitrite and shows strong fluorescence. HPF (Goryo Chemical, Hokkaido, Japan) was added to H2-dissolved solution (H2 group) or normal solution (control) at a final concentration of 5 μM. As in the ESR experiment, in 10 ml of the solution in the 50-ml plastic test tubes, US oscillation without irrigation and aspiration was performed for 10 seconds at 30% power. Immediately after US, fluorescence of the samples was measured by a plate reader (Wallac 1420 ARVO; PerkinElmer, Waltham, MA) with excitation at 485 nm and emission at 535 nm. All measurements were performed 4 times.
Effects of H2 in phacoemulsification in vivo
Rabbits were anesthetized via intramuscular injection of ketamine (30 mg/kg) and xylazine (4 mg/kg) and topical oxybuprocaine hydrochloride (Santen Pharmaceutical, Osaka, Japan) was used for local anesthesia. The US probe (Stellaris®, Bausch & Lomb) was introduced into the center of the anterior chamber through the incision and then continuous US oscillation with irrigation by H2-dissolved solution (H2 group) or normal solution (control) was performed for 90 seconds at 30% power of the US setting of the device (vacuum pressure: 175 mmHg; bottle height: 85 cm). To avoid the effect of probe manipulation, the phacoemulsification procedure was performed in a completely similar fashion in both groups. The US probe was moved slowly on the iris plane roundly without touching the lens. At 5 hours after the procedure, the rabbits were euthanized by overdose injection of ketamine. After the anterior segments were photographed using the ophthalmologic surgical microscope, the whole cornea was excised and submitted to the following experiments.
Image analysis of corneal edema
The excised corneas (control n = 4, H2 group n = 3) were photographed and analyzed using ImageJ software (Version 1.44, NIH, Bethesda, MD) as described previously35,36. Each image was captured using the same camera settings for gain and time and pixel intensity was analyzed for 25,000 pixels (500 × 500 pixels) at the center of the cornea. Background intensity was calculated from the untreated cornea and subtracted from each image.
Semiquantitative PCR for HO-1, CAT, SOD1 and SOD2 mRNA
HO-1 has been known to play an important role in cell membrane protection against various oxidative stresses25. CAT, SOD1 and SOD2 are also crucial for breaking down the harmful end products of oxidative phosphorylation37. The effect of H2 on their mRNA expression in the corneal endothelium was evaluated. At 5 hours after US exposure, the cornea was excised and the endothelial cells were immediately scraped using a blunt scalpel. Total RNA was extracted from corneal endothelial cells and subjected to reverse transcription, with portions of the resulting cDNA then subjected to real-time semi-quantitative PCR (qPCR) analysis with a 7500 Fast Real-Time PCR System (Life Technologies, Tokyo, Japan). The Fast Real-Time PCR System was used with the following primers: for HO-1, 5′-CAGGTGACTGCCGAGGGTTTTA-3′ (forward) and 5′-GGAAGTAGAGCGGGGCGTAG-3′ (reverse)38; for CAT, 5′-CCCAATAGGAGACAAACTGA-3′ (forward) and 5′-ACTCTCTCCGGAATTCTCTC-3′ (reverse) were designed using DNASIS Pro software (Hitachi Software Engineering Co., Ltd., Tokyo, Japan); for SOD1, 5′-GACGCATAACAGGACTGACCG-3′ (forward) and 5′-AACACATCAGCGACACCATTG-3′ (reverse)39, for SOD2, 5′-TGACGGCTGTGTCTGTTGGT-3′ (forward) and 5′-GCAGGTAGTAAGCGTGTTCCC-3′ (reverse)39, for rabbit glyceraldehyde -3-phosphate dehydrogenase (GAPDH) gene, 5′-GCCGCTTCTTCTCGTGCAG-3′ (forward) and 5′-ATGGATCATTGATGGCGACAACAT-3′ (reverse) (accession no. L23961)40. The cycling protocol entailed incubation at 90 °C for 10 s followed by 40 cycles of 95 °C for 5 s and 60 °C for 34 s. Relative gene expression was calculated using the standard curve method. The HO-1 mRNA levels were normalized to those of the housekeeping GAPDH gene. The HO-1/GAPDH ratio in untreated corneal endothelial cells was defined as 1.0. To assess the average value of the HO-1/GAPDH ratio, measurements were performed 5 times. Each sample was run in duplicate and each real-time PCR was repeated three times (control n = 7, H2 group n = 6).
The excised corneas were fixed in Bouin’s solution (Wako Pure Chemical Industries, Osaka, Japan) for 1 hour at 4 °C, washed 3 times for 10 minutes each in PBS with 1% Triton X-100 (Bio-Rad Laboratories, CA) (PBST) and treated with acetone for 3 minutes at −20 °C. They were further washed 3 times for 10 minutes with PBST and incubated in 10% horse serum diluted in PBST to block nonspecific staining. The corneas were then incubated in a 1:30 dilution of a monoclonal antibody against 8-OHdG (control n = 5, H2 group n = 6) or 4-hydroxy-2-nonenal (4-HNE) (control n = 3, H2 group n = 5) overnight at 4 °C (18). Both antibodies were purchased from the Japan Institute for the Control of Aging (Shizuoka, Japan). The corneas were washed with PBST 3 times for 10 minutes and incubated with horse biotinylated anti-mouse IgG (Vector Laboratories, Burlingame, CA) for 1 hour at room temperature. Tissues were then washed with PBST 3 times for 10 minutes and incubated with ABC reagent (Vector Laboratories) for 1 hour at room temperature. After being washed with PBST 3 times for 10 minutes, corneas were stained with DAB solution (Vector Laboratories) for 10 minutes at room temperature. Finally, they were washed with distilled water for 5 minutes each and mounted on slides.
Morphometric data from different regions in each eye were averaged to provide one value per eye. The mean and SD for these measurements were calculated for each group and comparisons between groups were made using the unpaired t-test (Stat Flex ver. 6, Artec, Osaka, Japan). A p value of <0.05 was considered significant.
This experiment was approved by the Animal Care and Use Committee of Nippon Medical School (27–045).
How to cite this article: Igarashi, T. et al. Hydrogen prevents corneal endothelial damage in phacoemulsification cataract surgery. Sci. Rep. 6, 31190; doi: 10.1038/srep31190 (2016).
Olson, L. E., Marshall, J., Rice, N. S. & Andrews, R. Effects of ultrasound on the corneal endothelium: I. The acute lesion. The British journal of ophthalmology 62, 134–144 (1978).
Pirazzoli, G., D’Eliseo, D., Ziosi, M. & Acciarri, R. Effects of phacoemulsification time on the corneal endothelium using phacofracture and phaco chop techniques. Journal of cataract and refractive surgery 22, 967–969 (1996).
Miyata, K. et al. Efficacy and safety of the soft-shell technique in cases with a hard lens nucleus. Journal of cataract and refractive surgery 28, 1546–1550 (2002).
Kim, E. K. et al. Endothelial protection: avoiding air bubble formation at the phacoemulsification tip. Journal of cataract and refractive surgery 28, 531–537 (2002).
Svensson, B. & Mellerio, J. Phaco-emulsification causes the formation of cavitation bubbles. Current eye research 13, 649–653 (1994).
Sippel, K. C. & Pineda, R. Jr. Phacoemulsification and thermal wound injury. Seminars in ophthalmology 17, 102–109 (2002).
Suzuki, H., Igarashi, T., Shiwa, T. & Takahashi, H. Efficacy of Ophthalmic Viscosurgical Devices in Preventing Temperature Rise at the Corneal Endothelium during Phacoemulsification. Current eye research, 1–5, doi: 10.3109/02713683.2015.1136420 (2016).
Suzuki, H., Oki, K., Igarashi, T., Shiwa, T. & Takahashi, H. Temperature in the anterior chamber during phacoemulsification. Journal of cataract and refractive surgery 40, 805–810, doi: 10.1016/j.jcrs.2013.08.063 (2014).
Riesz, P. & Kondo, T. Free radical formation induced by ultrasound and its biological implications. Free radical biology & medicine 13, 247–270 (1992).
Cameron, M. D., Poyer, J. F. & Aust, S. D. Identification of free radicals produced during phacoemulsification. Journal of cataract and refractive surgery 27, 463–470 (2001).
Takahashi, H. et al. Free radicals in phacoemulsification and aspiration procedures. Archives of ophthalmology 120, 1348–1352 (2002).
Murano, N., Ishizaki, M., Sato, S., Fukuda, Y. & Takahashi, H. Corneal endothelial cell damage by free radicals associated with ultrasound oscillation. Archives of ophthalmology 126, 816–821, doi: 10.1001/archopht.126.6.816 (2008).
Artola, A., Alio, J. L., Bellot, J. L. & Ruiz, J. M. Lipid peroxidation in the iris and its protection by means of viscoelastic substances (sodium hyaluronate and hydroxypropylmethylcellulose). Ophthalmic research 25, 172–176 (1993).
Takahashi, H., Suzuki, H., Shiwa, T. & Sakamoto, A. Alteration of free radical development by ophthalmic viscosurgical devices in phacoemulsification. Journal of cataract and refractive surgery 32, 1545–1548, doi: 10.1016/j.jcrs.2006.04.026 (2006).
Ohsawa, I. et al. Hydrogen acts as a therapeutic antioxidant by selectively reducing cytotoxic oxygen radicals. Nature medicine 13, 688–694, doi: 10.1038/nm1577 (2007).
Fu, Y. et al. Molecular hydrogen is protective against 6-hydroxydopamine-induced nigrostriatal degeneration in a rat model of Parkinson’s disease. Neuroscience letters 453, 81–85, doi: 10.1016/j.neulet.2009.02.016 (2009).
Hayashida, K. et al. Hydrogen inhalation during normoxic resuscitation improves neurological outcome in a rat model of cardiac arrest independently of targeted temperature management. Circulation 130, 2173–2180, doi: 10.1161/circulationaha.114.011848 (2014).
Qian, L., Mei, K., Shen, J. & Cai, J. Administration of hydrogen-rich saline protects mice from lethal acute graft-versus-host disease (aGVHD). Transplantation 95, 658–662, doi: 10.1097/TP.0b013e31827e6b23 (2013).
Terasaki, Y. et al. Hydrogen therapy attenuates irradiation-induced lung damage by reducing oxidative stress. American journal of physiology. Lung cellular and molecular physiology 301, L415–426, doi: 10.1152/ajplung.00008.2011 (2011).
Oharazawa, H. et al. Protection of the retina by rapid diffusion of hydrogen: administration of hydrogen-loaded eye drops in retinal ischemia-reperfusion injury. Investigative ophthalmology & visual science 51, 487–492, doi: 10.1167/iovs.09-4089 (2010).
Shimazaki, J., Amano, S., Uno, T., Maeda, N. & Yokoi, N. National survey on bullous keratopathy in Japan. Cornea 26, 274–278, doi: 10.1097/ICO.0b013e31802c9e19 (2007).
Keenan, T. D., Jones, M. N., Rushton, S. & Carley, F. M. Trends in the indications for corneal graft surgery in the United Kingdom: 1999 through 2009. Archives of ophthalmology 130, 621–628, doi: 10.1001/archophthalmol.2011.2585 (2012).
Ichihara, M. et al. Beneficial biological effects and the underlying mechanisms of molecular hydrogen - comprehensive review of 321 original articles. Medical gas research 5, 12, doi: 10.1186/s13618-015-0035-1 (2015).
Huang, A. J. et al. Impact of Corneal Endothelial Dysfunctions on Intraocular Oxygen Levels in Human Eyes. Investigative ophthalmology & visual science 56, 6483–6488, doi: 10.1167/iovs.15-17191 (2015).
Paine, A., Eiz-Vesper, B., Blasczyk, R. & Immenschuh, S. Signaling to heme oxygenase-1 and its anti-inflammatory therapeutic potential. Biochemical pharmacology 80, 1895–1903, doi: 10.1016/j.bcp.2010.07.014 (2010).
Hayashida, K. et al. Inhalation of hydrogen gas reduces infarct size in the rat model of myocardial ischemia-reperfusion injury. Biochemical and biophysical research communications 373, 30–35, doi: 10.1016/j.bbrc.2008.05.165 (2008).
Nagatani, K. et al. Effect of hydrogen gas on the survival rate of mice following global cerebral ischemia. Shock (Augusta, Ga.) 37, 645–652, doi: 10.1097/SHK.0b013e31824ed57c (2012).
Zhao, W. & Robbins, M. E. Inflammation and chronic oxidative stress in radiation-induced late normal tissue injury: therapeutic implications. Current medicinal chemistry 16, 130–143 (2009).
Glasser, D. B., Matsuda, M., Ellis, J. G. & Edelhauser, H. F. Effects of intraocular irrigating solutions on the corneal endothelium after in vivo anterior chamber irrigation. American journal of ophthalmology 99, 321–328 (1985).
McCarey, B. E., Polack, F. M. & Marshall, W. The phacoemulsification procedure. I. The effect of intraocular irrigating solutions on the corneal endothelium. Investigative ophthalmology 15, 449–457 (1976).
Nemet, A. Y. et al. Protective effect of free-radical scavengers on corneal endothelial damage in phacoemulsification. Journal of cataract and refractive surgery 33, 310–315, doi: 10.1016/j.jcrs.2006.10.031 (2007).
Rubowitz, A., Assia, E. I., Rosner, M. & Topaz, M. Antioxidant protection against corneal damage by free radicals during phacoemulsification. Investigative ophthalmology & visual science 44, 1866–1870 (2003).
Geffen, N. et al. Phacoemulsification-induced injury in corneal endothelial cells mediated by apoptosis: in vitro model. Journal of cataract and refractive surgery 34, 2146–2152, doi: 10.1016/j.jcrs.2008.08.024 (2008).
Setsukinai, K., Urano, Y., Kakinuma, K., Majima, H. J. & Nagano, T. Development of novel fluorescence probes that can reliably detect reactive oxygen species and distinguish specific species. The Journal of biological chemistry 278, 3170–3175, doi: 10.1074/jbc.M209264200 (2003).
Igarashi, T. et al. Direct comparison of administration routes for AAV8-mediated ocular gene therapy. Current eye research 38, 569–577, doi: 10.3109/02713683.2013.779720 (2013).
Takahashi, H. et al. Reactive gliosis of astrocytes and Muller glial cells in retina of POMGnT1-deficient mice. Molecular and cellular neurosciences 47, 119–130, doi: 10.1016/j.mcn.2011.03.006 (2011).
Abraham, N. G. & Kappas, A. Pharmacological and clinical aspects of heme oxygenase. Pharmacological reviews 60, 79–127, doi: 10.1124/pr.107.07104 (2008).
Liu, D., He, Z., Wu, L. & Fang, Y. Effects of induction/inhibition of endogenous heme oxygenase-1 on lipid metabolism, endothelial function and atherosclerosis in rabbits on a high fat diet. Journal of pharmacological sciences 118, 14–24 (2012).
Yu, Q. J. & Yang, Y. Function of SOD1, SOD2 and PI3K/AKT signaling pathways in the protection of propofol on spinal cord ischemic reperfusion injury in a rabbit model. Life sciences 148, 86–92, doi: 10.1016/j.lfs.2016.02.005 (2016).
Navarrete Santos, A., Ramin, N., Tonack, S. & Fischer, B. Cell lineage-specific signaling of insulin and insulin-like growth factor I in rabbit blastocysts. Endocrinology 149, 515–524, doi: 10.1210/en.2007-0821 (2008).
This work was supported in part by Grant-in-Aid for Scientific Research (c) (26462670 and 26462650) from the Ministry of Education, Culture, Sports, Science and Technology of Japan. The authors would like to thank Dr Kazuhira Takahashi for the production of H2 ocular irrigating solution and Dr Yasuhiro Terasaki for the preparation of the ESR experiment.
The authors declare no competing financial interests.
About this article
Cite this article
Igarashi, T., Ohsawa, I., Kobayashi, M. et al. Hydrogen prevents corneal endothelial damage in phacoemulsification cataract surgery. Sci Rep 6, 31190 (2016). https://doi.org/10.1038/srep31190
This article is cited by
Scientific Reports (2022)
Optimisation of Storage and Transportation Conditions of Cultured Corneal Endothelial Cells for Cell Replacement Therapy
Scientific Reports (2020)
RETRACTED ARTICLE: Therapeutic effect of molecular hydrogen in corneal UVB-induced oxidative stress and corneal photodamage
Scientific Reports (2017)