Creatine supplementation reduces the cerebral oxidative and metabolic stress responses to acute in utero hypoxia in the late-gestation fetal sheep.

Prophylactic creatine treatment may reduce hypoxic brain injury due to its ability to sustain intracellular ATP levels thereby reducing oxidative and metabolic stress responses during oxygen deprivation. Using microdialysis, we investigated the real-time in vivo effects of fetal creatine supplementation on cerebral metabolism following acute in utero hypoxia caused by umbilical cord occlusion (UCO). Fetal sheep (118 days' gestational age (dGA)) were implanted with an inflatable Silastic cuff around the umbilical cord and a microdialysis probe inserted into the right cerebral hemisphere for interstitial fluid sampling. Creatine (6 mg kg-1  h-1 ) or saline was continuously infused intravenously from 122 dGA. At 131 dGA, a 10 min UCO was induced. Hourly microdialysis samples were obtained from -24 to 72 h post-UCO and analysed for percentage change of hydroxyl radicals (• OH) and interstitial metabolites (lactate, pyruvate, glutamate, glycerol, glycine). Histochemical markers of protein and lipid oxidation were assessed at post-mortem 72 h post-UCO. Prior to UCO, creatine treatment reduced pyruvate and glycerol concentrations in the microdialysate outflow. Creatine treatment reduced interstitial cerebral • OH outflow 0 to 24 h post-UCO. Fetuses with higher arterial creatine concentrations before UCO presented with reduced levels of hypoxaemia ( PO2${P_{{{\rm{O}}_{\rm{2}}}}}$ and SO2${S_{{{\rm{O}}_{\rm{2}}}}}$ ) during UCO which associated with reduced interstitial cerebral pyruvate, lactate and • OH accumulation. No effects of creatine treatment on immunohistochemical markers of oxidative stress were found. In conclusion, fetal creatine treatment decreased cerebral outflow of • OH and was associated with an improvement in cerebral bioenergetics following acute hypoxia. KEY POINTS: Fetal hypoxia can cause persistent metabolic and oxidative stress responses that disturb energy homeostasis in the brain. Creatine in its phosphorylated form is an endogenous phosphagen; therefore, supplementation is a proposed prophylactic treatment for fetal hypoxia. Fetal sheep instrumented with a cerebral microdialysis probe were continuously infused with or without creatine-monohydrate for 10 days before induction of 10 min umbilical cord occlusion (UCO; 131 days' gestation). Cerebral interstitial fluid was collected up to 72 h following UCO. Prior to UCO, fetal creatine supplementation reduced interstitial cerebral pyruvate and glycerol concentrations. Fetal creatine supplementation reduced cerebral hydroxyl radical efflux up to 24 h post-UCO. Fetuses with higher arterial creatine concentrations before UCO and reduced levels of systemic hypoxaemia during UCO were associated with reduced cerebral interstitial pyruvate, lactate and • OH following UCO. Creatine supplementation leads to some improvements in cerebral bioenergetics following in utero acute hypoxia.

Assessing Creatine Supplementation for Neuroprotection against Perinatal Hypoxic-Ischaemic Encephalopathy: A Systematic Review of Perinatal and Adult Pre-Clinical Studies.

There is an important unmet need to develop interventions that improve outcomes of hypoxic-ischaemic encephalopathy (HIE). Creatine has emerged as a promising neuroprotective agent. Our objective was to systematically evaluate the preclinical animal studies that used creatine for perinatal neuroprotection, and to identify knowledge gaps that need to be addressed before creatine can be considered for pragmatic clinical trials for HIE. METHODS: We reviewed preclinical studies up to 20 September 2021 using PubMed, EMBASE and OVID MEDLINE databases. The SYRCLE risk of bias assessment tool was utilized. RESULTS: Seventeen studies were identified. Dietary creatine was the most common administration route. Cerebral creatine loading was age-dependent with near term/term-equivalent studies reporting higher increases in creatine/phosphocreatine compared to adolescent-adult equivalent studies. Most studies did not control for sex, study long-term histological and functional outcomes, or test creatine post-HI. None of the perinatal studies that suggested benefit directly controlled core body temperature (a known confounder) and many did not clearly state controlling for potential study bias. CONCLUSION: Creatine is a promising neuroprotective intervention for HIE. However, this systematic review reveals key knowledge gaps and improvements to preclinical studies that must be addressed before creatine can be trailed for neuroprotection of the human fetus/neonate.

The physiological effects of creatine supplementation in fetal sheep before, during, and after umbilical cord occlusion and global hypoxia.

The aim of this study was to investigate the effects of direct creatine infusion on fetal systemic metabolic and cardiovascular responses to mild acute in utero hypoxia. Pregnant ewes (n = 28) were surgically instrumented at 118 days gestation (dGa). A constant intravenous infusion of creatine (6 mg·kg-1·h-1) or isovolumetric saline (1.5 mL·h-1) began at 121 dGa. After 10 days, fetuses were subjected to 10-min umbilical cord occlusion (UCO) to induce mild global hypoxia (saline-UCO, n = 8; creatine-UCO, n = 7) or sham UCO (saline-control, n = 6; creatine-control, n = 7). Cardiovascular, arterial blood gases and metabolites, and plasma creatine were monitored before, during, and then for 72 h following the UCO. Total creatine content in discrete fetal brain regions was also measured. Fetal creatine infusion increased plasma concentrations fivefold but had no significant effects on any measurement pre-UCO. Creatine did not alter fetal physiology during the UCO or in the early recovery stage, up to 24 h after UCO. During the late recovery stage, 24-72 h after UCO, there was a significant reduction in the arterial oxygen pressure and saturation in creatine fetuses (PUCO × TREATMENT = 0.02 and 0.04, respectively). At 72 h after UCO, significant creatine loading was detected in cortical gray matter, hippocampus, thalamus, and striatum (PTREATMENT = 0.01-0.001). In the striatum, the UCO itself increased total creatine content (PUCO = 0.019). Overall, fetal creatine supplementation may alter oxygen flux following an acute hypoxic insult. Increasing total creatine content in the striatum may also be a fetal adaptation to acute oxygen deprivation.NEW & NOTEWORTHY Direct fetal creatine supplementation increased plasma and cerebral creatine concentrations but did not alter fetal body weight, basal cardiovascular output, or blood chemistry. Creatine-treated fetuses displayed changes to arterial oxygenation 24-72 h after acute global hypoxia. An increase in striatum total creatine levels following UCO was also noted and suggests that increasing creatine tissue availability may be an adaptive response against the effects of hypoxia.