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. 2011 Nov 23;32(2):232–241. doi: 10.1038/jcbfm.2011.164

Mild hypoxemia during initial reperfusion alleviates the severity of secondary energy failure and protects brain in neonatal mice with hypoxic-ischemic injury

Zoya V Niatsetskaya 1,4, Pradeep Charlagorla 1,4, Dzmitry A Matsukevich 2, Sergey A Sosunov 1, Korapat Mayurasakorn 1, Veniamin I Ratner 1, Richard A Polin 1, Anatoly A Starkov 3, Vadim S Ten 1,*
PMCID: PMC3272612  PMID: 22108720

Abstract

Reperfusion triggers an oxidative stress. We hypothesized that mild hypoxemia in reperfusion attenuates oxidative brain injury following hypoxia-ischemia (HI). In neonatal HI-mice, the reperfusion was initiated by reoxygenation with room air (RA) followed by the exposure to 100%, 21%, 18%, 15% oxygen for 60 minutes. Systemic oxygen saturation (SaO2), cerebral blood flow (CBF), brain mitochondrial respiration and permeability transition pore (mPTP) opening, markers of oxidative injury, and cerebral infarcts were assessed. Compared with RA-littermates, HI-mice exposed to 18% oxygen exhibited significantly decreased infarct volume, oxidative injury in the brain mitochondria and tissue. This was coupled with improved mitochondrial tolerance to mPTP opening. Oxygen saturation maintained during reperfusion at 85% to 95% was associated (r=0.57) with the best neurologic outcome. Exposure to 100% or 15% oxygen significantly exacerbated brain injury and oxidative stress. Compared with RA-mice, hyperoxia dramatically increased reperfusion CBF, but exposure to 15% oxygen significantly reduced CBF to values observed during the HI-insult. Mild hypoxemia during initial reperfusion alleviates the severity of HI-brain injury by limiting the reperfusion-driven oxidative stress to the mitochondria and mPTP opening. This suggests that at the initial stage of reperfusion, a slightly decreased systemic oxygenation (SaO2 85% to 95%) may be beneficial for infants with birth asphyxia.

Keywords: brain, hypoxemia, hypoxia-ischemia, neuroprotection, oxidative stress, reperfusion

Introduction

Reintroduction of O2 to the ischemic brain during reperfusion is critical for tissue survival. However, the same event triggers an oxidative stress, one of the central mechanisms of reperfusion injury. Current clinical practice is the maintaining systemic oxygenation at normoxemic (oxygen saturation (SaO2)=95% to 99%) levels in infants with hypoxia-ischemia (HI)-brain injury. However, there is a large body of experimental evidence that systemic hyperoxemia during early 30 to 60 minutes of reperfusion markedly exacerbates brain injury in newborn animals subjected to HI-insult (Koch et al, 2008; Munkeby et al, 2004; Richards et al, 2007). The primary mechanism for this hyperoxemia-driven worsening of HI-brain injury is exacerbation of an oxidative stress associated with excessive generation of reactive oxygen species (ROS).

During HI, the ability of mitochondria to generate ATP by oxidative phosphorylation is severely inhibited (Caspersen et al, 2008; Gilland et al, 1998; Ten et al, 2010). Reoxygenation/reperfusion restores mitochondrial ADP-phosphorylating capacity, normalizing ATP content in the postischemic brain (Lorek et al, 1994). However, following several hours of reperfusion, mitochondria again exhibit a profound decline in ATP-generation capacity, known as a secondary energy failure (Halestrap, 2010; Kuroda et al, 1996; Lorek et al, 1994; Puka-Sundvall et al, 2000). The molecular mechanism proposed to explain secondary energy failure is the concept of mitochondrial membrane permeabilization secondary to opening of mitochondrial permeability transition pore (mPTP). Triggered by accumulation of Ca++, an opening of mPTP results in dissipation of mitochondrial proton-motive force, which renders mitochondria incapable of energy production and ultimately leads to mitochondrial swelling and release of pro-apoptotic proteins. The formation of mPTP during reperfusion can be triggered by ROS, even in the presence of intra-mitochondrial Ca++ chelator (Kim et al, 2006). We hypothesized that mild hypoxemia during early reperfusion limits O2 supply for the reperfusion-accelerated generation of ROS. This attenuates oxidative stress to the mitochondrial matrix, and improves mitochondrial tolerance to Ca++-induced mPTP opening. Because mPTP opening is considered as a key mechanism for secondary energy failure, we propose that mild hypoxemia maintained during early reperfusion will improve post-HI-brain recovery.

Materials and methods

Induction of Unilateral Hypoxia-Ischemia and Study Groups

In accordance with the National Institute of Health Guidelines for animal research, all animal procedures for these experiments were reviewed and approved by the Institutional Animal Care and Use Committee of the Columbia University. We used the Rice-Vannucci model of HI-brain injury adapted to p10 neonatal mice (Ten et al, 2003, 2004). Briefly, following a permanent ligation of the right carotid artery, at 90 minutes of recovery pups were exposed to hypoxia (8% O2 balanced N2) for 20 minutes. The ambient temperature during hypoxia was maintained at 36.5°C to 37.5°C by placing the hypoxic chamber in a neonatal isolette (Airshield, Mooresville, NC, USA). Following 5 minutes of reoxygenation with room air (RA), all mice were randomly assigned to four study groups: RA—reoxygenation continued with RA, FiO2=0.21 (initial n=45, one mice died before infarct volume assessment, final n=44); mild hypoxemia-mice were reoxygenated with FiO2=0.18 (initial n=45, two mice died before infarct volume assessment; final n=43); severe hypoxemia-mice were reoxygenated with FiO2=0.15 (initial n=30, three mice died before infarct volume assessment; final n=27); hyperoxemia-mice were reoxygenated with FiO2=1.0 (initial n=20, six mice died before infarct volume assessment; final n=14) (Figure 1A). The sample size for each group of mice was determined according to the power analysis. We assumed that mice reperfused with 18% oxygen will exhibit 20% difference (n=45, α=0.05, 1–β=0.80) and mice reperfused with 15% oxygen ∼30% difference (n=30, α=0.05, 1–β=0.80) in their infarct volumes compared with the littermates reperfused in RA. Because a detrimental effect of hyperoxic reperfusion on the extent of HI-brain injury has been shown earlier, the number of mice in this (100% O2 reperfusion) group was restricted compared with the mice exposed to hypoxemic and normoxemic (control) reperfusion.

Figure 1.

Figure 1

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(A) Experimental design (see Materials and methods). (B, C) Cerebral infarct volume and representative coronal sections of the brains obtained at 24 hours of reperfusion from hypoxia-ischemia (HI)-mice reoxygenated with 21%, 18%, 15%, or 100% oxygen and stained with triphenyl-tetrazolium chloride (TTC). Data are presented as mean±s.e., study groups and P values are indicated. (D) Cerebral infarct volume in groups of mice with different oxygen saturation (SaO2 <85%, n=7, SaO2=85% to 95%, n=14 and SaO2 > 95%, n=16) recorded during initial 60 minutes of reperfusion. Data are presented as mean±s.e., study groups and P values are indicated. (E) Polynomial regression analysis for correlation between the brain infarct volume and mean SaO2 recorded during initial 60 minutes of reperfusion in mice reoxygenated with 21% O2 (open circles), 18% O2 (checkered circles), or 15% O2 (black circles).

The exposure to different FiO2 was performed in 1 L tightly sealed glass jars at the ambient temperature 32°C. Gas flow was maintained at 2 L/min. Following 60 minutes of exposure to a different FiO2, mice were returned to their dams. To minimize a temperature-related variability in the extent of brain injury, during initial 12 hours of reperfusion mice were kept in an isolette at the ambient t=32°C. At 24 hours of reperfusion, mice were killed by decapitation, the brains were harvested, sectioned into 1-mm thick coronal slices, and stained with 2% triphenyl-tetrazolium chloride. Digital images of infarcted (pale-white) and viable (red) areas of the brains were traced (Adobe Photoshop 4.0.1, Adobe Systems Incorporated) and analyzed (NIH image 1.62, NIH, Bethesda, MA, USA) by an investigator ‘blinded' to a study groups. The extent of brain injury (direct infarct volume) was expressed as a percentage of the infarcted hemisphere ipsilateral to the carotid artery ligation.

Measurements of Systemic Oxygen Saturation and Cerebral Blood Flow

In randomly selected mice (n=37), changes in SaO2 were recorded during hypoxic exposure and initial 65 minutes of reoxygenation initiated with RA and maintained with different FiO2. To record SaO2, a probe was placed around the neck and SaO2 values were constantly recorded using mouse pulseoximeter (Starr Life Sciences, Pittsburgh, PA, USA). The mean values of SaO2 recorded over the entire duration of HI-insult or 65 minutes of reperfusion were used for analysis. Changes in the cerebral blood flow (CBF) were recorded in a separate cohort of mice (n=15) using laser Doppler flowmeter (PeriFlux 5000, Perimed, Järfälla, Sweden) as described (Slinko et al, 2007). Briefly, before the hypoxic exposure, under isoflurane anesthesia, Doppler probes were placed on the skull (2 mm posterior and 3 mm lateral to the bregma) using 15 to 20 cm fiberoptic extensions. Changes in CBF were continuously recorded during HI and reoxygenation. Mean CBF values obtained during HI and reperfusion and expressed as percentage of the pre-HI level were used for analysis.

Mitochondrial Isolation

The brain nonsynaptosomal mitochondria were isolated as described (Caspersen et al, 2008) with minor modification: the tissue was homogenized manually using a dounce homogenizer (Wheaton, Millville, NJ, USA) with 0.2 mm differential (10 strokes) followed by 0.1 mm differential (10 strokes) and the final mitochondrial pellet was resuspended in 0.07 mL of albumin-free sucrose buffer (Ten et al, 2010).

Mitochondrial Ca++ Upload Capacity Assay

Mitochondrial Ca++ upload capacity (threshold for mPTP opening) was estimated using Hitachi F-7000 spectrofluorimeter equipped with magnetic stirring, thermocontrol and Calcium green 5N fluorescence probe (Ex. 488; Em. 532; Invitrogen, Carlsbad, CA, USA). In brief, isolated mitochondria (0.05 mg) were incubated in 1 mL of 10 mmol/L MOPS-Tris buffer pH 7.4 containing 120 mmol/L KCl, 1 mmol/L KH2PO4, 10 μM EGTA, 5 mmol/L succinate, 2.5 mmol/L glutamate, and 1 μM Calcium green 5N. At 100 seconds of incubation, once fluorescence reached a steady-state tracing, 10 nmol CaCl2 were added every 50 seconds. The amount of Ca++ consumed by mitochondria until mPTP opened (evidenced by the Ca++ leak-out) was recorded and expressed in nmoles of Ca++ per mg of mitochondrial protein. The incubation conditions are described in the Figure 4 legend.

Mitochondrial Respiration Assay

Mitochondrial respiration was measured using a Clark-type electrode (Oxytherm, Hansatech, UK) as described (Caspersen et al, 2008). Mitochondria (0.05 mg of protein) were added to 0.5 mL of respiration buffer composed of 200 mmol/L sucrose, 25 mmol/L KCl, 2 mmol/L KH2PO4, 5 mmol/L HEPES-KOH (4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid) pH 7.2, 5 mmol/L MgCl2, 0.2 mg/mL of bovine serum albumin, fatty acid free (BSA), 30 μM Ap5A (P1,P5-di(adenosine 5′)-pentaphosphate—an inhibitor of adenylate kinase), 10 mmol/L glutamate, and 5 mmol/L malate at t=32°C. To initiate the phosphorylating respiration (state 3), 100 nmol of ADP was added to the mitochondrial suspension. Rates of O2 consumption were expressed in O2 nmol/mg mitochondrial protein/min. The RCR (respiratory control ratio) was calculated as the ratio of the state 3 respiration rate to the resting respiration rate (state 4) recorded after the phosphorylation of ADP has been completed.

Assessment of Oxidative Damage in the Brain Tissue and Mitochondrial Matrix

The extent of oxidative brain injury was analyzed by visual detection and semiquantification of immunopositivity for markers of lipid peroxidation (4-hydroxy-nonenal, 4-HNE) and protein peroxinitration (3-nitrotyrosine, 3-NT). In brief, at 5 hours of reperfusion, the brains were harvested from randomly selected HI-mice, fixed in 4% paraformaldehyde and soaked in 30% sucrose overnight. In all, 20-μm thick coronal sections were blocked (10% donkey serum) and incubated with rabbit polyclonal anti-4-HNE (1:500) and anti-3-NT antibodies (1:100) as described (Zhu et al, 2007). Samples were examined using Bio-Rad 2000 confocal laser-scanning device (Hercules, CA, USA) attached to a Nikon E800 microscope (San Diego, CA, USA). The 4-HNE and 3-NT immunoreactivity was analyzed by the count of the ratio of immunopositive/total cells in two nonadjacent fields ( × 40) of injured cortex at three different bregma levels (−1.0, 0, +1.0 mm). Thus, six areas of cortex were analyzed for each brain sample and mean value (%) of immunopositive cells per each mouse was used for statistical analysis. Only those mice that have developed signs of brain injury (absence or residual expression of microtubule-associated protein 2 (MAP2)) were used for data analysis.

To assess the extent of oxidative injury to the mitochondrial matrix, at 5 hours of reperfusion, aconitase activity was measured in cerebral mitochondrial fraction as described (Morrison, 1954). Frozen-thawed mitochondria were mixed with the reaction buffer (50 mmol/L Tris-HCl, pH 7.4, 0.6 mmol/L MnSO4, 5 mmol/L Na citrate, 0.5 mmol/L nicotinamide adenine dinucleotide phosphate (NADP), 1 U/mL iso-citrate dehydrogenase) in a 96-well plate and the absorbance changes at 340 nm were followed for 10 minutes with a plate reader (Tecan Infinite M200, San Jose, CA, USA). The aconitase activity was expressed in mU per minute per mg of mitochondrial protein. Aconitase activity is a well-known marker for oxidative mitochondrial damage (Bulteau et al, 2003; Sadek et al, 2002).

Statistics

The analysis of variance with Fisher's post-hoc analysis was used to compare three or more groups. The t-test analysis was used to compare two groups. The difference in values was considered statistically significant if P⩽0.05.

Results

The Extent of Brain Injury Depends on Oxygen Saturation During Initial Reperfusion

Mice exposed to 18% O2 exhibited a significant (P=0.006) reduction in their infarct volumes compared with the RA-reoxygenated littermates (Figures 1B and 1C). In contrast, mice exposed to 15% O2 demonstrated a dramatic (P<0.0001) exacerbation of brain injury (Figures 1B and 1C). Similarly, hyperoxia applied during early reperfusion also caused a significant (P=0.003) extension in cerebral infarct volume compared with RA-reoxygenated mice (Figures 1B and 1C). Oxygen saturation values during HI did not differ between groups (data not shown), indicating that the severity of hypoxemia was similar in all HI-mice. As expected, changes in FiO2 during reperfusion altered systemic SaO2 in a dose-dependent manner. Mice kept on RA demonstrated mean±s.d. values of SaO2 96.9%±1.95%, mice reperfused with 18% O2—91%±5.9% and mice kept on 15% O2—82.4%±7.27%. When HI-mice reperfused with various FiO2 (0.21 or 0.15 or 0.18) were regrouped according to the mean SaO2 value recorded during initial 60 minutes of reperfusion (SaO2 > 95% or SaO2=85% to 95% or SaO2 <85%), we found that mild hypoxemia (SaO2 85% to 95%) was associated with a significantly better neuroanatomical outcome compared with HI-mice with an SaO2 >95% (Figure 1D). Those mice with an SaO2 <85% during initial reperfusion exhibited the most extensive brain injury (Figure 1D). Polynomial regression analysis revealed a significant (P=0.001, r=0.56) correlation between SaO2 recorded during initial 60 minutes of reperfusion and cerebral infarct volume assessed at 24 hours after HI-insult (Figure 1E).

FiO2 Alters Cerebral Blood Flow Recovery During Initial Reperfusion

Analysis of CBF changes in response to reperfusion with different FiO2 revealed three patterns of CBF recovery. Mice exposed to FiO2=1.0 demonstrated a dramatic (up to 300% of the pre-HI value) elevation of the CBF in the postischemic hemisphere (Figures 2A and 2B). In contrast, those mice that were breathing with FiO2=0.15, after brief normalization of the CBF in response to initial reoxygenation with RA, demonstrated significant reduction in the CBF, consistent with the values observed during HI-insult (Figures 2A and 2B). Mice reoxygenated with RA or 18% O2 exhibited similar patterns of CBF recovery (Figures 2A and 2B). An approximation of O2 delivery to the postischemic hemisphere during the 60 minutes of reperfusion (mean CBF in percentage of preischemic value × mean SaO2) showed that reoxygenation with 15% O2 substantially limited O2 delivery (≈4,200 a.u.) compared with mice reoxygenated with RA (≈10,670 a.u.) or 18% O2 (≈9,100 a.u.).

Figure 2.

Figure 2

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(A) Changes in cerebral blood flow (CBF) in the ipsilateral hemisphere during hypoxia-ischemia (HI)-insult and reoxygenation with either 21% (open circles, n=6), 18% (checkered circles, n=6), 15% (black circles, n=5), or 100% (striped circles, n=5) oxygen. *P=0.002 and **P=0.0002 indicate differences between summated CBF values recorded between initial 10 and 60 minutes of reperfusion. (B) Representative tracing of CBF changes in response to HI and reperfusion in mice reperfused in 21%, 18%, 15%, or 100% oxygen. All CBF values are percentage in relation to the pre-HI value in each animal (100%).

FiO2 During Initial Reperfusion Alters the Extent of Oxidative Damage to Brain Mitochondria and Tissue

Semiquantitative analysis of immunoexpression of 4-HNE and 3-NT revealed that at 5 hours of reperfusion HI-mice exposed to 100% O2 on reperfusion developed the most extensive oxidative injury of lipids and proteins in their brains. In contrast, mice exposed to 18% O2 exhibited significantly decreased proportion of 3-NT-positive cells compared with their RA-reoxygenated littermates (Figures 3A and 3B). The reduction in the proportion of 4-HNE-positive cells in these mice did not reach statistical significance (P=0.09) compared with the RA-reoxygenated littermates (Figure 3C). To our surprise, mice reoxygenated with the lowest FiO2=0.15 exhibited increased oxidative changes in cerebral lipids and proteins compared with their 18% O2 reoxygenated littermates (Figures 3A–3C). At the same time point of reperfusion, mitochondria from all HI-mice demonstrated significant loss in aconitase activity compared with naives. Those HI-mice reperfused in 18% O2 exhibited a significantly better-preserved mitochondrial aconitase activity compared with the littermates reperfused with FiO2=0.15 or 1.0 and, most importantly, compared with the HI-littermates reoxygenated with 21% O2 (Figure 3D). Associated with exacerbated brain injury, mice reperfused with 15% or 100% oxygen demonstrated significantly (P=0.02) greater loss in their aconitase activity compared with the littermates reoxygenated with RA (Figure 3D).

Figure 3.

Figure 3

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(A) Representative images of ischemic cerebral cortex immunostained for 3-nitrotyrosine (3-NT) (pink) in hypoxia-ischemia (HI)-mice following 5 hours of reperfusion with different O2 concentration (indicated) applied during initial 60 minutes of reperfusion. (B, C) Semiquantitative analysis of 3-NT and 4-hydroxy-nonenal (4-HNE) immunopositive cells count in the ischemic cortex in HI-mice reoxygenated with different FiO2 (indicated). Data are presented as mean±s.e., study groups (n=12 in each group) and P values are indicated. (D) Aconitase activity in the brain mitochondria isolated from HI-mice at 5 hours of reperfusion with different FiO2 applied during initial 60 minutes after HI (naives, n=16; 0.21, n=16; 0.15, n=14; 0.18, n=15; 1.0, n=15). Data are presented as mean±s.e.; *P⩽0.003 compared with naives. The color reproduction of this figure is available on the Journal of Cerebral Blood Flow and Metabolism journal online.

Mild Hypoxemia Limits Mitochondrial Permeability Transition Pore Opening and Secondary Inhibition of Oxidative Phosphorylation During Reperfusion

Compared with naives, the HI-insult significantly reduced Ca++ threshold for mPTP opening in all groups of mice (Figures 4A and 4B). However, the brain mitochondria isolated from the mice reperfused with 18% O2 demonstrated significantly better ability to buffer a Ca++ load compared with all other HI-mice (Figures 4A and 4B). In contrast, mice exposed to 15% or 100% O2 exhibited significantly poorer Ca++-buffering capacity compared not only with naive mice, but also compared with RA-reoxygenated littermates (Figures 4A and 4B). Figure 4C demonstrates that Ca++-buffering capacity assay used in this study tests cyclosporine-A-sensitive mitochondrial membrane permeabilization, which results in cytochrome-C release.

Figure 4.

Figure 4

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(A) Ca++-buffering capacity in mitochondria isolated at 5 hours or reperfusion from the ipsilateral hemisphere of hypoxia-ischemia (HI)-mice reoxygenated with different FiO2 (0.21, 0.15, and 1.0, n=14; 0.18, n=13; naives, n=11). *P⩽0.026 compared with naives, #P⩽0.03 compared with room air (RA)-reoxygenated mice. (B) Representative tracings of Ca++-buffering capacity measurements in cerebral mitochondria isolated from the ipsilateral hemisphere of HI-mice reoxygenated with different O2 concentration (indicated). Arrows indicate Ca++ supplementation. (C) Tracing of Ca++-buffering capacity measurement in mitochondria isolated from naive p10 mouse with subsequent immunoblot analysis for the release of cytochrome-C (Cyt C) secondary to mitochondrial permeability transition pore (mPTP) opening. Mitochondria 0.25 mg/mL, Ca++ load=10 nmol each, arrows indicate Ca++ chelation with EGTA. *Tracing from control organelles, **the same organelles tested in the presence of cyclosporine-A (CsA; 1.6 μmol/L) and ***the same organelles with CsA in which Ca++ load was completed before the mPTP had opened. Reaction buffer was centrifuged (10,000 g, 5 minutes, 4°C) and the presence of the cytochrome-C in the supernatant was detected by western blot. COX IV (cytochrome oxidase IV) was used as mitochondrial marker. The rest of the experimental conditions are described in the Materials and methods.

At the same time point of reperfusion (5 hours following HI-insult), mitochondria isolated from all groups of HI-mice demonstrated a significantly decreased state 3, ADP-phosphorylating, respiration rate compared with naive littermates (Figure 5A). However, compared with all other groups of HI-mice, mice reoxygenated with 18% O2 exhibited significantly better-preserved ADP-phosphorylating respiration rate (Figure 5A). The RCR was also significantly decreased in HI-mice (except those animals that were reoxygenated with 18% O2) compared with the naives (Figure 5B). No significant difference was detected in the state 4 (resting respiration rate) among all HI-mice (data not shown). Importantly, at this time point of reperfusion, mitochondrial ADP-phosphorylating respiration rate strongly (r2=0.74) correlated with the ability of mitochondria to buffer Ca++ load (Figure 5C).

Figure 5.

Figure 5

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(A, B) Oxygen consumption rate during phosphorylating respiration (state 3) and respiratory control ratio (RCR) at 5 hours of reperfusion in mitochondria from the ipsilateral hemisphere of hypoxia-ischemia (HI)-mice reoxygenated with different FiO2: 0.21, n=10; 0.18, n=10; 0.15, n=6; 1.0, n=6 compared with naives (n=6). *P⩽0.005 and #P⩽0.03 compared with naives. (C) Linear regression analysis for correlation between O2 consumption rate during state 3 respiration and Ca++-buffering capacity in the brain mitochondria isolated from HI-mice reoxygenated with room air (RA) (striped circles), 18% O2 (checkered circles), 100% O2 (grey circles), or 15% O2 (black circles) compared with naives (open circles).

Discussion

This study demonstrates that changes in systemic oxygenation during the initial 60 minutes of reperfusion significantly alter the extent of HI-brain injury in neonatal mice. While, the reoxygenation with FiO2 1.0% or 0.15% markedly exacerbated brain damage, mild hypoxemia by the exposure to 18% oxygen was associated with a significant reduction in cerebral infarct volume compared with the RA-reperfused littermates. This suggests that different levels of systemic oxygenation at the initial stage of reperfusion contribute to the mechanisms involved in either propagation of HI-brain injury or cerebral recovery. There are numerous reports that hyperoxemia initiated during resuscitation and maintained for the initial 30 to 60 minutes of reperfusion is detrimental for brain recovery following HI-insult (Koch et al, 2008; Munkeby et al, 2004; Richards et al, 2007). However, it has never been shown that therapeutic maintenance of subnormal oxygenation during early reperfusion protects neonatal brain against HI-injury. It is important to note that in this study, the FiO2 was changed following 5 minutes of resuscitation initiated with RA. Earlier, we have shown that 5 minutes of reoxygenation with RA was required to achieve a full recovery of the cerebral circulation, the end point of resuscitation in this model (Presti et al, 2006). Thus, the neuroprotection exerted by the mild hypoxemia in our study is not applicable to the resuscitation paradigm, in which resuscitation with 18% oxygen was not beneficial for biochemical cerebral recovery in asphyxiated piglets (Jantzie et al, 2008).

Reintroduction of oxygen to ischemic tissue at the onset of reperfusion is the major initiating event for the reperfusion-driven oxidative stress. One of the sources for oxidative radicals in postischemic cells is mitochondrion. The ROS of mitochondrial origin can damage cells in the brain and heart during ischemia–reperfusion (Battaglia et al, 2010; Kim et al, 2006; Loor et al, 2010). We propose that mild hypoxemia applied shortly after HI limits O2 availability for the reperfusion-accelerated ROS formation in the mitochondria, and this attenuates an oxidative stress. Although, it is still debatable whether in vivo mitochondria increase or decrease generation of ROS in response to hypoxia (reviewed in Bell et al, 2005), it has been shown that isolated mitochondria always decrease emission of ROS proportionally to the extent of O2 deprivation (Hoffman et al, 2007). The reperfusion with O2 depleted buffer prevented the death of myocardiocytes following in vitro ischemia–reperfusion injury (Kim et al, 2006). In our study, HI-mice reoxygenated with 18% O2 exhibited decreased cerebral expression of markers for protein oxidative damage, 3-NT compared with the littermates reperfused in RA. Moreover, mild hypoxemia during reperfusion was associated with limited oxidative injury to the mitochondrial matrix, as evidenced by significantly better-preserved aconitase activity compared with all groups. This was coupled with significantly better-preserved tolerance to Ca++-induced opening of mitochondrial mPTP. Although, the exact molecular mechanisms regulating a formation of mPTP on reperfusion are not well understood, it is known that mitochondrial ROS trigger an opening of mPTP during ischemia (Loor et al, 2010) and reperfusion (Di Lisa et al, 2009; Lemasters et al, 2009). The direct effect of ROS on induction of mPTP has been reported even with a low Ca++ load or in the absence of cyclophilin-D (Basso et al, 2005; Kim et al, 2006). Ca++-induced opening of mPTP has been suggested as a primary molecular mechanism for secondary energy failure and subsequent necrotic and apoptotic cell death in reperfusion (Baines et al, 2005; Halestrap and Pasdois, 2009; Nakagawa et al, 2005). Because HI-mice exposed to 18% O2 during early reperfusion exhibited improved mitochondrial tolerance to the opening of Ca++ mPTP, we propose that mild hypoxemia maintained during early reperfusion protects the immature brain by attenuation of the severity of secondary energy failure. Indeed, the mice reoxygenated with 18% O2 exhibited a significantly better preservation of ADP-phosphorylating respiration rates compared with all other groups of HI-mice tested at 5 hours of reperfusion, the time point when secondary energy failure occurs in this model (Puka-Sundvall et al, 2000; Ten et al, 2010). The tight relationship between the capacity of mitochondria to buffer a Ca++ load and to phosphorylate ADP suggests that mPTP opening deleteriously affects oxidative phosphorylation in reperfusion, leading to secondary energy failure. It has been shown that inhibition of cyclophilin-D-dependent formation of mPTP with cyclosporine-A attenuated secondary depression in mitochondrial-phosphorylating capacity in immature pigs with traumatic brain injury (Kilbaugh et al, 2011). Thus, attenuation of secondary energy failure could be suggested as a mechanistic read-out in this study. Of note, there were no significant differences between groups of HI-mice in the state 4 of mitochondrial respiration rates (data not shown). This indicates that the decrease in RCR values in these mice mostly reflects an inhibition in phosphorylating respiration rate, rather than uncoupling of oxidative phosphorylation.

It is important to note that data on pathogenic role of Ca++-triggered mPTP in the developing HI-brain are not straightforward. Wang et al (2009) has reported that neonatal mice (as opposite to adult mice) deficient in cyclophilin-D (the only known functional component of mPTP) exhibited exacerbation of HI-brain injury. These data challenge cyclophilin-D-dependent mPTP opening as a pathogenic mechanism for secondary energy failure in the developing HI-brain. Similarly, posttreatment with cyclosporine-A, antagonist of cyclophilin-D, did not protect neonatal rats against HI-brain injury (Puka-Sundvall et al, 2001). Recently, however, Hwang et al (2010) demonstrated that, cyclosporin-A, injected immediately after HI-insult significantly protected the developing brain, attenuating both necrotic and apoptotic cell death in neonatal rats. Similar results were obtained in neonatal rats subjected to a mild focal cerebral ischemia–reperfusion (Leger et al, 2010). In our study, the attenuation of secondary energy failure, defined by the preservation of mitochondrial ADP-phosphorylating activity was strongly (r2=0.74) associated with improved mitochondrial tolerance to mPTP opening. These data, at least partially, suggest a pathogenic role of mPTP in HI-injury to the developing brain.

When HI-mice were exposed to a greater degree of hypoxia (15% O2), this was associated with robust exacerbation of HI-brain injury. Compared with the littermates reperfused in normoxia and mild (18% O2) hypoxia, these mice exhibited a secondary decline in CBF, although initially, their CBF fully recovered in response to reoxygenation with RA. The degree of this reduction in CBF was comparable to that observed during HI, suggesting that the exposure to 15% O2 during reperfusion caused a secondary HI-insult, which may account for exacerbation of cerebral injury. While mild hypoxemia was associated with markedly attenuated oxidative stress, a further decrease in oxygenation resulted in an opposite effect, exacerbation of oxidative damage. This suggests that, if the brain experiences a secondary ischemic event, the oxidative injury propagates even in an environment with a low O2 content. For example, during oxygen–glucose deprivation, neuronal mitochondria markedly accelerated ROS generation in spite of the minimal O2 availability; when mitochondrial membrane potential collapsed the ROS generation decreased (Abramov et al, 2007). Similarly, cardiomyocytes exhibited enhanced mitochondrial superoxide production during simulated ischemia, leading to an opening of mPTP (Loor et al, 2010). Thus, an ischemic stimulation of mitochondrial ROS release may account for exacerbation of oxidative injury in HI-mice subjected to 15% O2 during reperfusion. Indeed, similarly to 100% O2 reoxygenated littermates, the brain mitochondria isolated from these mice exhibited a significant decrease in aconitase activity and Ca++-buffering capacity, suggesting that the severity of oxidative stress to mitochondria was comparable to that in HI-mice exposed to hyperoxia. Secondary ischemia may cause an additional intra-mitochondrial Ca++ flux (Kristian, 2004), further contributing to the loss of Ca++-buffering capacity.

To dissect-out the contribution of an oxidative stress driven by reperfusion, we exposed HI-mice to extreme hyperoxia (FiO2=1.0). Our data are in full agreement with previous reports, demonstrating exacerbation of oxidative neurologic damage in hyperoxic HI-mice compared with normoxemic littermates (Koch et al, 2008). The novel findings are that hyperoxic reperfusion was associated with dramatic overcirculation in the post-HI-brain. Given that exposure to 100% O2 during reperfusion substantially increases paO2 (Richards et al, 2007), the post-HI overcirculation is expected to result in excessive O2 delivery, potentiating generation of ROS and oxidative injury. In animals subjected to a focal brain ischemia–reperfusion injury, reactive/malignant hyperemia during reperfusion was strongly associated with exacerbation of oxidative stress, edema, intra-cranial hypertension, and the extent of injury (Heiss et al, 1997; Lee et al, 2004; Perez-Asensio et al, 2010). This part of our study offers an additional mechanistic explanation for deleterious effect of hyperoxic reperfusion on the outcome of HI-brain injury.

In conclusion, to our knowledge this is the first report, demonstrating that mild hypoxemia (SaO2=85% to 95%) maintained during early reperfusion protects immature brain against HI-insult. One of the mechanisms for this neuroprotection is attenuation of mitochondrial oxidative stress and improved mitochondrial tolerance to Ca++-triggered mPTP opening. The therapeutic effect of hypoxemic reperfusion, however, becomes detrimental if hypoxemia is severe enough to cause a secondary decline in cerebral circulation. This work offers the experimental background for the development of a novel therapeutic strategy in which the maintenance of subnormal SaO2 without deterioration of CBF during early reperfusion limits HI-injury to the immature brain.

The authors declare no conflict of interest.

Footnotes

This work was supported by NIH Grants NS 071121 and NS 056146 (VT).

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