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Prediction of Adverse Outcome with Cerebral Lactate Level and Apparent Diffusion Coefficient in Infants with Perinatal Asphyxia¹

¹ From the Departments of Radiology (M.K.Z., L.G.A., T.Y.P., A.A.T.), Neurology (A.d.P.), and Biostatistics (D.Z.), Children’s Hospital, Harvard Medical School, Boston, Mass. From the 2000 RSNA scientific assembly. Received November 7, 2001; revision requested January 21, 2002; final revision received May 1; accepted May 29. Address correspondence to A.A.T., Department of Surgery, Massachusetts General Hospital, Harvard Medical School, 51 Blossom St, Rm 261, Boston, MA 02114 (e-mail: atzika@partners.org).

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
PURPOSE: To compare the predictive value for adverse outcome of quantitative cerebral lactate level and of apparent diffusion coefficient (ADC) in infants with perinatal asphyxia in the early postnatal period.

MATERIALS AND METHODS: Lactate-choline ratios determined with proton magnetic resonance (MR) spectroscopy and ADC determined with diffusion MR imaging in basal ganglia and thalami in 26 full-term neonates (age range, 1–10 days) were compared with severity of acute hypoxic-ischemic encephalopathy and long-term clinical outcome. Differences in metabolites between outcome groups were evaluated with the nonparametric Kruskal-Wallis test and the Dunn test. Logistic regression was performed to examine the predictive value of each metabolite for differentiating normal from abnormal or fatal clinical outcome. The likelihood ratio test was used to assess the statistical significance of each metabolite.

RESULTS: Logistic regression confirmed that lactate-choline ratio could be used to differentiate normal (n = 5) from abnormal (n = 14) or fatal (n = 6) outcome (P < .001). The probability of an adverse outcome exceeded 95% for a lactate-choline ratio of 1.0. Even when analyses were restricted to the early postnatal period, lactate-choline ratio was still a significant predictor of adverse outcome (P = .001). Although ADC images were useful in clinical examination of these infants, quantitative ADCs were not predictive of outcome (P = .82).

CONCLUSION: Higher lactate-choline ratios in basal ganglia and thalami of infants with perinatal asphyxia were predictive of worse clinical outcomes. Absolute ADC in the same brain regions did not indicate a statistically significant relationship with clinical outcome. Cerebral lactate level is useful in identifying infants who would benefit from early therapeutic intervention.

© RSNA, 2002

Index terms: Asphyxia, 14.591 • Brain, diffusion, 14.12144 • Brain, MR, 14.121411 • Cerebral palsy • Infants, central nervous system, 14.591 • Infants, newborn • Magnetic resonance (MR), spectroscopy, 14.12145

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Early identification of neonates with perinatal asphyxia who are at risk for hypoxic-ischemic encephalopathy (HIE) is crucial because of the cascade of biochemical events (ie, energy failure, acidosis, free radical formation, calcium accumulation, lipid peroxidation, and neurotoxic reactions to glutamate and nitric oxide) that eventually may lead to neuronal necrosis and/or apoptosis (1,2). The introduction of oxygen at the onset of reperfusion may stimulate these processes further, so that ongoing injury ensues. In neonatal animals and, probably, in human infants, these processes may evolve rapidly and may require early intervention before irreversible brain injury occurs.

Therefore, timely intervention within this therapeutic window requires early identification of neonates at risk for HIE (2). Early identification is hindered by a lack of accurate quantifiable predictors of long-term neurodevelopmental outcome (3). A number of biochemical markers in the blood serum and cerebrospinal fluid have been proposed for that purpose, and these include neuron-specific enolase, glial fibrillary acidic protein, and brain-specific creatine kinase (4,5). However, the results are often delayed, and cerebrospinal fluid collection may be difficult in critically ill neonates.

The utility of magnetic resonance (MR) imaging methods in the assessment of HIE has been suggested by some researchers (6–18). Proton MR spectroscopy has a potential for use in accurate prediction of adverse outcome in neonates with perinatal asphyxia (19) through noninvasive evaluation of the in vivo metabolic and biochemical status of the brain, including the brain of the newborn infant (15,20). In some investigations, the value of diffusion-weighted MR imaging in identifying acute or hyperacute changes following HIE has been suggested (16,21–23). Furthermore, quantitative measurements of the apparent diffusion coefficient (ADC) of water have the potential of being used to measure the severity of cellular hypoxic-ischemic injury in the brain, and these ADC measurements may be useful for prediction of clinical outcome (22,24).

The purpose of this study was to compare the predictive value for adverse outcome of the quantitative cerebral lactate level and of the ADC in infants with perinatal asphyxia during the early postnatal period.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Clinical Evaluation
Twenty-six full-term infants (14 girls, 12 boys) aged 1–10 days (gestational age range, 38–42 weeks) who met the clinical criteria for the diagnosis of HIE that was due to perinatal asphyxia (defined later) (18) were included in the study from August 1998 to September 1999. We excluded infants with congenital malformations, inherited metabolic disorders, or infection. Institutional review board approval was obtained for this study. The institutional review board did not require informed consent from the parents, because MR spectroscopy was an approved clinical diagnostic procedure at Children’s Hospital, Boston, Mass.

Perinatal asphyxia was diagnosed by one of the authors (A.d.P.) if three criteria were met: evidence of fetal distress (eg, abnormal fetal heart rate and/or metabolic acidosis with cord blood pH < 7.1), immediate neonatal depression (eg, 5-minute Apgar score 5), and neonatal HIE. Neonatal HIE was categorized into three grades by the pediatric neurologist (A.d.P.), with the most severe grade within the first 72 hours of life assigned to each patient. Mild HIE was defined as an altered level of consciousness that included somnolence and/or irritability, with periods of spontaneous eye opening, and jitteriness, abnormal muscle tone, and abnormal reflexes. Moderate HIE was defined as stupor with absence of spontaneous but presence of stimulated eye opening, abnormal muscle tone, seizures, and absence of brainstem dysfunction. Severe HIE was defined as coma with no spontaneous or elicited eye opening, seizures, and brainstem dysfunction with abnormal cranial nerve function and/or respiratory abnormalities.

The electroencephalographic (EEG) recordings were graded by the pediatric neurologist (A.d.P.) into four levels of severity largely on the basis of the background activity. Specifically, an EEG was considered mildly abnormal if the background was less mature than expected for gestational age ("dysmature") (eg, excessive background discontinuity) or showed excessive spikes, sharp discharges, or slowing with normal amplitude. A moderately abnormal EEG had low amplitude (5–15 µV). Severe EEG abnormalities included low voltage (<5 µV), burst suppression pattern, or EEG evidence of status epilepticus. Profound EEG abnormalities included those with an isoelectric (ie, no detectable electrocortical activity) EEG tracing.

Initial MR imaging studies were performed as early in postnatal life as possible, from 7 hours to 10 days old. Eight patients underwent at least one follow-up MR imaging study from 6 days to 12 months old.

After discharge, all infants were reexamined clinically for their neurodevelopmental progress. Clinical outcome was classified as normal, abnormal (ie, on the basis of the absence or presence of an abnormality at the follow-up neurodevelopmental examination), or fatal.

MR Imaging and Proton MR Spectroscopy
All MR imaging and proton MR spectroscopic examinations were performed by using a 1.5-T whole-body MR system (GE Medical Systems, Milwaukee, Wis) with a quadrature head coil. The MR imaging protocol included spin-echo and fast spin-echo MR pulse sequences. Spin-echo images were sagittal T1-weighted MR images (repetition time [TR] msec/echo time [TE] msec, 600/20; two signals acquired). Fast spin-echo images were transverse T2-weighted MR images (3,200/85, one signal acquired, echo train length of eight). The field of view was 20 cm, the section thickness was 4 mm with a gap of 1 mm, and the acquisition matrix was 256 x 192. Where necessary, sedation was induced with midazolam hydrochloride (Versed; Hoffman-LaRoche, Nutley, NJ) administered intravenously at a dose of 0.1 mg per kilogram of body weight or with chloral hydrate (Major Pharmaceuticals, Rosemont, Ill) administered orally at a dose of 50 mg/kg.

Use of proton MR spectroscopy added approximately 4 minutes to the MR imaging examination, and the total examination time did not exceed 40 minutes; proton MR spectroscopy was performed by using either a single-voxel technique and/or a multivoxel long-echo (TE, 144 msec) point-resolved spatially localized spectroscopic method (25). Ideally, we planned to perform both single- and multivoxel MR spectroscopy; however, typically the protocol was reduced to either single- or multivoxel MR spectroscopy, depending on the time requirements. In any case, the voxels were placed by the technologist who was guided by the radiologist.

Other typical parameters for single-voxel MR spectroscopy were as follows: TR, 1,500 msec; 192 signals acquired; 2,500 ± 1,250 SD; and 1,048 complex data points with a voxel size of approximately 2 cm³. For multivoxel MR spectroscopy, other parameters were as follows: TR, 1,000 msec; 16 x 16 x 1 phase-encoding steps; and 160-mm field of view with a nominal voxel size of 1.0–1.2 cm³. Long-echo point-resolved spatially localized spectroscopy with its high signal-to-noise ratio includes no contributions from resonances caused by fat; thus, this technique helps to reveal accumulated lactate. Metabolites of biological importance, such as N-acetylaspartate (NAA), choline-containing compounds, total creatine, and lactate, may be detected by using this technique (26). For metabolite quantification, we used peak area ratios.

For several reasons, we selected the lactate-choline ratio, although others have described the predictive value of the ratio of lactate to NAA (10). Specifically, the temporal pattern of changes in lactate and NAA likely proceed along different, varying, and poorly understood time courses, features that may generate potentially misleading ratios of lactate to NAA at different time points after injury. Although early NAA changes may be modest, caused by means other than neuronal loss (27), the more delayed changes in choline concentration expected from the later postnecrotic myelinolysis are likely to provide a more stable denominator. Others have used total creatine as a proton MR spectroscopic reference metabolite because of its relative stability after hypoxia-ischemia and better reflection of deranged energy metabolism (17,19). However, the total creatine peak is modulated by varying TE and may therefore not reflect lactate accumulation as accurately as does the lactate-choline ratio. Our lactate-choline ratios were in agreement with published values of others (15).

Diffusion-weighted MR imaging was performed by using a line-scan method that resulted in transverse images (field of view, 20 x 15 cm; effective section thickness, 7 mm; gap, 0 mm; acquisition matrix, 128 x 128, interpolated to 256 x 192) obtained with b values of 5 sec/mm² and of 750 sec/mm² as the maximum b values applied along the three orthogonal directions (16). The minimum imaging time was 5 minutes 49 seconds. In contrast to methods used in previous studies (21,22,28), we evaluated the quantitative ADC value in a consistent region of interest (ROI) rather than delineate a topographic "map" of abnormal diffusion. The ROI, that is, the area that included the basal ganglia and the thalami, was chosen because of the known vulnerability of these regions to hypoxic-ischemic injury (29). The second author (L.G.A.) selected the ROIs for the ADC measurements. In this task, he was supervised by the first (M.K.Z.), third (T.Y.P.), and last (A.A.T.) authors. The ROIs were square (0.7–1.1 cm³) and matched as closely as possible the MR spectroscopic voxels of interest and thus served the comparative aspects of our analysis. ADC values were compared with our own normative data and with the data of others (23,30).

Biostatistical Analyses
The Pearson product moment correlation coefficient (r) was used to assess the strength of association between continuous variables, which included the lactate-choline ratios and the ADC values. The Spearman rank correlation () was used to correlate the ADC and the proton MR spectroscopic measurements, as well as the severity of HIE and EEG results. Differences in lactate-choline ratio, ADC, and neurologic outcome were illustrated by using box plots (31). Differences in metabolites between outcome groups were evaluated by using the nonparametric Kruskal-Wallis test and the Dunn test. Analysis of variance (ANOVA) was also performed by using parametric and nonparametric methods to ensure that differences or lack of differences between groups was consistent. Logistic regression analysis was performed to examine the predictive value of each metabolite for differentiating normal from abnormal or fatal clinical outcome. The likelihood ratio test was used to assess the statistical significance of each metabolite, and probabilities of an adverse outcome were derived according to the maximum likelihood estimation (32). The associations between clinical outcome and grade of HIE and EEG abnormality were ascertained by using the Pearson ² test for trend. Statistical analysis was conducted by using software packages (SAS, version 6.12, SAS Institute, Cary, NC; SPSS, version 11.0, SPSS, Chicago, Ill). A two-tailed P value of less than .05 was considered to indicate a statistically significant difference.

	RESULTS

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Clinical Evaluation
The maximal severity of clinical HIE was mild in one infant, moderate in 10 infants, and severe in 12 infants. Insufficient early clinical data precluded reliable retrospective grading in three infants (patients 19, 25, 26; Table 1). We performed EEG in all but one infant (patient 16; Table 1). In the neonatal period, the EEG results were categorized as mild in four infants, moderate in three infants, severe in 14 infants, and profound in four infants.

The infant (patient 16) with mild HIE had a normal outcome. Of the 10 infants with moderate HIE, four (patients 5, 6, 14, 18) had normal outcomes and six (patients 1, 4, 8, 12, 13, 21) had abnormal outcomes. Of the 12 infants with severe HIE, five (patients 2, 17, 22–24) had fatal outcomes and six (patients 7, 9–11, 15, 20) had abnormal outcomes.

Of the three infants with a moderate EEG abnormality, the outcome was normal in one (patient 5) and abnormal in two (patients 10, 21). Of the 14 infants with severely abnormal EEG results, four died (patients 22–24, 26), nine had an abnormal outcome (patients 1, 4, 7–9, 12, 13, 19, 20), and one (patient 6) had a normal outcome at follow-up. Of the four infants with profound EEG abnormalities, two had fatal outcomes (patients 2, 17), and one had an abnormal outcome (patient 11); in one patient (patient 3), the neurodevelopmental outcome was not known. A ² test of trend indicated that a significant association was observed between severity of EEG results and outcome (P = .008).

Findings at MR Imaging and Proton MR Spectroscopy
In 20 of 26 patients in this study, T2 abnormalities were observed at initial or follow-up conventional MR imaging (Table 2). Qualitative evaluation of conventional T2-weighted and diffusion-weighted MR imaging findings at initial and follow-up examinations are presented in Table 2 together with the long-term neurodevelopmental outcome. Table 2 also shows the lactate-choline ratios and ADC measurements in the basal ganglia and thalami in 26 patients. In some patients, more than one measurement was performed. Correlations were determined on the basis of the total measurements across all patients. Figures 1–3 show MR images and proton MR spectra in two infants with fatal (Figs 1, 2) and abnormal (Fig 3) neurodevelopmental outcomes. Figure 2 shows multivoxel (at day 1 of life) and single-voxel (at day 2 of life) proton MR spectroscopic images, respectively. Multivoxel proton MR spectroscopic measurements were determined; however, for our analyses, we included only measurements from the basal ganglia and thalami.

View larger version (57K): [in this window] [in a new window] [Download PPT slide]   Figure 1. Patient 2. Transverse T2-weighted MR image, ADC map, and proton MR spectrum obtained in a 1-day-old full-term male infant. This infant had severe neonatal HIE, persistent seizures, perinatal depression (Apgar scores 2 and 1 at 1 and 5 minutes, respectively), and metabolic acidosis that was due to placental abruption. The infant died at 1 day old. T2-weighted fast spin-echo MR image (3,000/140) shows subtle thalamic hyperintensity (arrow). MR spectrum from an ROI () within the deep gray matter shows a prominent lactate (Lac) peak, with a lactate-choline (Cho) ratio of 1.51. ADC map (calculated by using a line-scan diffusion sequence with 2,850/106 and b = 1,000 sec/mm2) at the level of the basal ganglia shows a reduced ADC value of 0.5 µm2/msec. In this infant, both clinical data and MR imaging findings combined with proton MR spectroscopic variables correlated well with the fatal outcome. tCr = total creatine.

View larger version (77K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Patient 26. Transverse T2-weighted fast spin-echo (3,000/140) and diffusion-weighted MR images and proton MR spectra at 1 and 2 days old in a full-term male infant. This infant had perinatal depression (Apgar scores 8 and 9 at 1 and 5 minutes, respectively) that was due to placental abruption and developed persistent neonatal seizures. T2-weighted MR images show minimal hyperintensity (arrow) in the thalami bilaterally. At multivoxel proton MR spectroscopy (MRS) at 1 day old, lactate (Lac) accumulation in the basal ganglia was revealed; ROI () includes the basal ganglia. At 2 days old, single-voxel MR spectrum from within deep gray matter showed high levels of lactate (lactate-choline [Cho] ratio = 1.56), and the patient died on that day. Favorable clinical variables could not be used to predict the fatal outcome in this infant, but MR imaging findings combined with proton MR spectroscopic variables were used to do so. tCr = total creatine.

View larger version (52K): [in this window] [in a new window] [Download PPT slide]   Figure 3. Patient 10. Transverse T2-weighted fast spin-echo (3,000/140) and diffusion-weighted MR images and proton MR spectrum in a 3-day-old full-term male infant. This infant had severe HIE, perinatal depression (Apgar scores 3 and 7 at 1 and 5 minutes, respectively) after placental abruption, persistent seizures, and metabolic acidosis. T2-weighted images show subtle hyperintensity (arrow) in the thalami. This infant had an abnormal neurodevelopmental outcome at 13 months. At proton MR spectroscopy (ROI is indicated []), an increased lactate (Lac) level in the thalamus was revealed. ADC map (calculated by using a line-scan diffusion sequence with 2,850/106 and b = 1,000 sec/mm2) showed restricted diffusion in the thalamus (ADC = 0.45 µm2/msec). Cho = choline, tCr = total creatine.

The lactate-choline ratio correlated significantly with the Apgar score at 5 minutes (Pearson r = -0.50, P = .02) but not at 1 minute (Pearson r = -0.22, P = .33). The lactate-choline ratio correlated positively with EEG results (Spearman = 0.45, P = .02) and grading of HIE (Spearman = 0.72, P < .001). However, the lactate-choline ratio did not correlate with the ADC (Pearson r = -0.10; P = .59).

Results of multiple comparisons testing, performed by using the Kruskal-Wallis test and the Dunn test, indicated that the lactate-choline ratio could be used to differentiate neonates with a normal outcome from those with an abnormal or a fatal outcome. Figure 4 presents the median values and interquartile ranges of lactate-choline ratios for the three outcome groups. No significant differences for ADC (P = .82) were detected among the three groups (Fig 4). The logistic regression model confirmed a significant positive relationship between the lactate-choline ratio and the likelihood of an adverse outcome (likelihood ratio test = 13.5, P < .001; Fig 5). For instance, a lactate-choline ratio of 0 was associated with a 25% probability of an adverse outcome; a ratio of 0.25, with a 75% probability of an adverse outcome; a ratio of 0.75, with a 90% probability of an adverse outcome; and a ratio of 1.00, with a 95% probability of an adverse outcome (Fig 5). Logistic regression demonstrated no significant relationship between ADC and outcome (P = .91).

View larger version (19K): [in this window] [in a new window] [Download PPT slide]   Figure 4. Box plots show relationship between (A) lactate-choline ratio (Lac/Cho) obtained by using proton MR spectroscopy and (B) ADC obtained by using diffusion-weighted MR imaging in the first 10 days of life and neurologic outcome. Outcome was normal in five infants, abnormal in 14, and fatal in six. In a box plot, the box is divided at the median (50th percentile). The box length is the interquartile range, and the top and bottom of the box represent the upper and lower quartiles. The error bars extend to the largest and smallest observed data points within 1.5 interquartile ranges from the top and bottom of the box, respectively. A shows the significant difference (P < .001) in the lactate-choline ratio of the three groups (ie, fatal, abnormal, and normal). The n represents the number of measurements. The lactate-choline ratio was higher in the fatal group, compared with that in both normal and abnormal groups (P < .001). The lactate-choline ratio was higher in the abnormal group, compared with that in the normal group (P = .004). B shows similar ADCs in the three groups (P = .82).

View larger version (19K): [in this window] [in a new window] [Download PPT slide]   Figure 5. Graph shows the significant inverse relationship between lactate-choline ratio (Lac/Cho) and the probability of an adverse outcome (likelihood ratio test = 13.5, 1 df, P < .001). Note that at a lactate-choline ratio of 1.00, the probability of an adverse outcome exceeds 95%.

With respect to the ADC, the Kruskal-Wallis test and the parametric ANOVA revealed no significant differences among the three groups (P = .90 and P = .85, respectively). Logistic regression analysis indicated that the ADC was not a significant predictor that could be used to differentiate normal from adverse outcomes (P = .82).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
In this study, we observed a strong association between the lactate-choline ratio in the basal ganglia and the thalami and both the severity of acute neonatal HIE and long-term neurodevelopmental outcome. These relationships remained statistically significant even when analyses were confined to MR imaging measurements within the first 5 days of life, a period of critical importance for clinical decision making. Furthermore, the majority of the infants had reduced quantitative ADC values in the basal ganglia and thalami. However, these absolute ADC values were not predictors of neurologic outcome. These findings suggest that diffusion-weighted MR imaging measurements are sensitive to hypoxic-ischemic injuries but lack specificity for use in predicting outcome in the population of asphyxiated newborn infants in this study.

To discuss our findings in the context of the cerebral cellular events and their temporal evolution, a brief review of the relevant pathophysiology of HIE is warranted. Cellular hypoxia triggers a mitochondrial response (33) that involves anaerobic glycolysis and lactate accumulation (34). Cellular energy failure inactivates critical membrane ionic pumps (eg, sodium, potassium, and adenosine triphosphatase), which leads to osmoregulatory failure and causes cytotoxic edema (35). Also, disruption of outer mitochondrial membrane permeability, which is regulated with physiologic conditions, has important implications for cell bioenergetics and cell survival (36).

With the onset of oxygenated reperfusion, recovery of cerebral energy status ensues while the lactate level begins to decrease. However, even with normal postreperfusion hemodynamics and oxygenation, a delayed form of energy failure with a secondary increase in lactate level and cytotoxic edema (37) may develop, with onset between 8 and 24 hours of reperfusion (38–43). The debate regarding the precise mechanisms of delayed energy failure is discussed elsewhere (2). After irreversible cellular injury, brain cells die by necrotic lysis or apoptosis. Axonal degeneration is more delayed and followed by myelinolysis, which releases substances such as choline. After 3 days, activated phagocytic cells infiltrate the injured area and remove cellular debris. These cells, which may persist in the areas for months, generate high lactate concentrations (19,39).

Finally, during the period of active gliosis, increased production by astrocytes could increase cerebral lactate levels (44,45). The tissue water characteristics following reperfusion evolve over time and are determined by factors such as cell lysis, release of osmotically active debris, postischemic vasogenic edema, and compromised blood-brain barrier permeability (46), all of which result in an increase in extracellular water. MR imaging methods that provide insights into the pathophysiologic characteristics of HIE include diffusion MR imaging, which depicts cytotoxic edema; T2-weighted MR imaging, which maps vasogenic edema; and MR spectroscopy, which is sensitive to tissue bioenergetics (47).

In most patients in this study, initial or follow-up MR imaging demonstrated abnormalities, and this finding is in agreement with data in previous studies (48,49) but does not support findings in other reports on the use of MR imaging in neonates (21) and adults (50). According to the study by Ning et al (48), early T2 abnormalities in the infants in our study may be attributed to vasogenic and/or cytotoxic edema or to an alteration in brain protein. Although the diagnosis of neonatal HIE presents a challenge to the neuroradiologist because of the undermyelinated brain (51), absence of T2 abnormalities in four of the infants in this study may imply asynchronous performance of MR imaging and development of vasogenic edema or other alterations.

In studies with animal models of HIE injury (40,41,45,52–55), the close temporal relationship between changes in cerebral lactate level and ADC during both the primary and secondary periods of energy failure were described. In a number of studies in animals and humans, spectroscopy, diffusion imaging, and other MR imaging techniques have been used to examine the temporal evolution of cerebral lactate levels and water diffusion after focal and global hypoxic-ischemic injuries (56–59). For the sake of clarity, we will discuss separately the postischemic changes in the cerebral lactate level and findings of diffusion-weighted MR imaging in our study and in those of others.

Cerebral Lactate Levels after Hypoxia-Ischemia
Our findings support results mentioned in previous studies (13,15,19,39,44,45,60,61). Increased cerebral lactate levels have been found at proton MR spectroscopy in infants who were a few hours to several months old (19,39,44,45,60,62). As outlined elsewhere, there are at least three mechanisms, separated in time, that may produce an increase in cerebral lactate levels after a global hypoxic-ischemic injury; some of these mechanisms include anaerobic glycolysis during the injury, secondary energy failure (45) associated with delayed mitochondrial dysfunction, and lactate generated by infiltrating macrophages during the repair phase (63). In the infants in our study, the intrauterine and/or intrapartum injury and resuscitation at birth help to exclude a primary form of energy failure as a mechanism for cerebral lactate level increase.

Any subsequent episodes of hypotension in the infants in our study were treated aggressively and promptly, and because of this treatment, ongoing or recurrent HIE was unlikely. In our study, since initial lactate-choline ratios were determined within the first 72 hours of life in most cases, a substantial contribution from lactate-generating macrophages was unlikely (63). Although the time course of the cerebral lactate level increase is attributable to delayed mitochondrial failure and has been defined clearly as a biphasic response in experimental models (45), a systematic follow-up study in infants is lacking. In this study, it is likely that the infants with increased cerebral lactate levels were in this phase of secondary energy failure at initial proton MR spectroscopy.

Furthermore, our data highlight another important point, namely, that it is not merely the presence but rather the level of cerebral lactate, as assessed by using noninvasive in vivo proton MR spectroscopy, that is the critical determinant of outcome. This is clearly depicted in the graph in Figure 5, which suggests that a threshold level of lactate-choline ratio, determined early in postnatal life to identify neonates at risk for irreversible injury, can be achieved. As shown in Figure 5, a lactate-choline ratio of approximately 1.00 indicates a greater than 95% probability of adverse neurodevelopmental outcome.

Even for lactate-choline ratios less than 1.00, the probability for adverse outcome is still high. Therefore, our study findings suggest, and it is well accepted, that absence of a cerebral lactate level at proton MR spectroscopy generally can be used to predict a normal outcome (9). Nevertheless, some infants with normal developmental outcome (three infants in our study) had low levels of cerebral lactate, a finding that is likely secondary to the milder perinatal asphyxia in these patients. Similar findings have been reported in previous studies (39,64).

ADC at Diffusion-weighted MR Imaging
In our study, the majority of infants had cerebral areas of restricted diffusion at the time of initial diffusion-weighted MR imaging, findings that are consistent with those in previous reports of focal and diffuse hypoxic-ischemic injury in infants and adults (21,50). Findings of previous studies in newborn infants (21,22) have suggested a relationship between diffusion changes on diffusion-weighted MR images and adverse outcome. Other researchers have indicated that regions of restricted diffusion can be used to predict the topography of brain lesions on later conventional MR images (21,65) and correlate well with short-term clinical outcome (22,65).

Parsons et al (28) combined diffusion-weighted MR imaging and proton MR spectroscopy in adults with stroke and achieved results similar to ours, namely, that the lactate-choline ratio could be used to predict outcome, but findings at diffusion-weighted MR imaging could not be used to do so. However, a fundamental difference exists between the application of diffusion-weighted MR imaging in our study and that used in previous studies (21,22,28). In previous studies, diffusion-weighted MR imaging was used to detect the presence or absence of abnormal diffusion or to measure its extent.

Our approach was based on data from animal models (40,41) that indicated a close temporal association between changes in the cerebral energy status and changes in the cerebral ADC. As such, we used the absolute ADC as a surrogate indicator of cellular energy status in a specific cerebral region (ie, the basal ganglia and thalami) known to have particularly high energy demands and vulnerability to energy failure in the full-term newborn. We found that although ADCs in the basal ganglia and thalami were reduced in the majority of the infants in this study, these values were not predictive of neurodevelopmental outcome. The reasons for this finding are not clear but may relate to a threshold effect of energy failure on osmoregulation, cytotoxic edema, and water diffusion.

Currently, there is no known threshold ADC below which irreversible cell damage occurs. In fact, the basic question of whether areas of restricted diffusion on diffusion-weighted MR images remain potentially viable or are irreversibly committed to infarction remains unanswered (66,67). Nevertheless, false-negative results in human neonates in the early postnatal period may be explained by experimental MR imaging studies in animals. Findings in these studies suggest that after the acute hypoxic-ischemic injury, which is accompanied by primary cytotoxic edema, cells recover transiently because of reversible alterations of physiologic water compartmentation, and both T2- and diffusion-weighted MR images may be normal (48,53–55,68). Another explanation is that apoptosis that is caused early in HIE is not detected by using diffusion-weighted or perfusion MR imaging (69).

On the other hand, our true-positive results may be explained by a secondary cytotoxic swelling, which follows the primary cytotoxic edema and is characterized by a combination of swollen glial cells and lysed neurons that are already necrotic. This swelling allows both cytotoxic and vasogenic edema to coexist and results in a low ADC and an increased T2 (53,55). Therefore, in agreement with findings in our study, it appears that single measurements of the ADC have limited prognostic value following perinatal asphyxia. Our results confirm findings in preliminary reports (70,71) as well as observations of others that suggest that diffusion-weighted MR imaging may help to identify (23), but may cause underestimation (62,72) of, the extent of injury that results from perinatal asphyxia.

Current Limitations and Future Directions
Our study, in general, has limitations inherent to studies of perinatal asphyxia in human newborns. Nevertheless, we were focused on identifying early (ie, in less than 72 hours of life) cerebral MR imaging predictors of neurodevelopmental outcome rather than on tracking changes in these measurements over time. Since we lacked an a priori protocol for follow-up MR imaging studies, we are unable to comment meaningfully on the evolution of MR changes over time in these infants. In addition, our study is limited by the absence of age-matched control subjects, although such control subjects were not required by our study design. However, we compared our values with those in control subjects in the literature (23,30,73). Unlike data in animal studies but common to data in other clinical studies of perinatal asphyxia, the exact timing, duration, and intensity of injury were not known in the patients in this study. Also, since lactate may not be visualized with the currently used techniques for detection, the importance of using lactate editing techniques (74), which help to avoid contributions from protons other than those from lactate, must be emphasized.

Since the lactate level and ADC follow a biphasic change after hypoxic-ischemic injury, although, in longitudinal experimental animal studies, the lactate level did not normalize (45) in a manner similar to that of the ADC (53,54), the appropriate timing of the MR imaging examination should be decided (62,75). In addition, a threshold value of the lactate level, as suggested by the results of the present study, that could reliably be used to identify irreversible brain injury must be determined. Meanwhile, quantitative diffusion anisotropy, provided by diffusion tensor MR imaging, which promises to be more sensitive to tissue microstructure (30), may be a pertinent quantitative predictor, in addition to the ADC, in newborns with perinatal asphyxia. Finally, imaging with radioactively labeled annexin V and proton lipid MR spectroscopy may have a role in the detection of apoptosis (69,76) that develops after perinatal asphyxia and, thus, may be useful in identification of neonates who might benefit from neuroprotective strategies.

In conclusion, in this study, findings of advanced combined in vivo MR imaging techniques were used to predict adverse outcome in infants with perinatal asphyxia. Our data suggest the added value of using the cerebral lactate level. Determined by using proton MR spectroscopic findings as noninvasive predictors of clinical outcome, the cerebral lactate level can be used in the identification of infants who would benefit from therapeutic intervention. Therapeutic intervention would include use of neuroprotective strategies during the early postnatal period. Absolute ADC measurements were not predictive of adverse outcome. Both conventional and diffusion-weighted MR imaging demonstrated abnormal findings as early as 1 day old.

	ACKNOWLEDGMENTS

 
The authors thank Joseph J. Volpe, MD, for his invaluable review of the manuscript and Pek L. Khong, MBBS, for assistance with MR imaging studies.

	FOOTNOTES

 
Abbreviations: ADC = apparent diffusion coefficient, ANOVA = analysis of variance, EEG = electroencephalogram, HIE = hypoxic-ischemic encephalopathy, NAA = N-acetylaspartate, ROI = region of interest, TE = echo time, TR = repetition time

Author contributions: Guarantors of integrity of entire study, all authors; study concepts, A.A.T., M.K.Z.; study design, all authors; literature research, M.K.Z., A.A.T., L.G.A.; clinical studies, T.Y.P., A.A.T.; data acquisition, M.K.Z., T.Y.P., A.A.T.; data analysis/interpretation, A.A.T., L.G.A., D.Z.; statistical analysis, D.Z.; manuscript preparation, M.K.Z., A.A.T.; manuscript definition of intellectual content, all authors; manuscript editing, A.A.T., A.d.P.; manuscript revision/review and final version approval, all authors.

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