Suppressive action of endogenous adenosine on ovine fetal nonshivering thermogenesis

Animal welfare aspects in respect of the slaughter or killing of pregnant livestock animals (cattle, pigs, sheep, goats, horses)

This scientific opinion addresses animal welfare aspects of slaughtering of livestock pregnant animals. Term of Reference (ToR) 1 requested assessment of the prevalence of animals slaughtered in a critical developmental stage of gestation when the livestock fetuses might experience negative affect. Limited data on European prevalence and related uncertainties necessitated a structured expert knowledge elicitation (EKE) exercise. Estimated median percentages of animals slaughtered in the last third of gestation are 3%, 1.5%, 0.5%, 0.8% and 0.2% (dairy cows, beef cattle, pigs, sheep and goats, respectively). Pregnant animals may be sent for slaughter for health, welfare, management and economic reasons (ToR2); there are also reasons for farmers not knowing that animals sent for slaughter are pregnant. Measures to reduce the incidence are listed. ToR3 asked whether livestock fetuses can experience pain and other negative affect. The available literature was reviewed and, at a second multidisciplinary EKE meeting, judgements and uncertainty were elicited. It is concluded that livestock fetuses in the last third of gestation have the anatomical and neurophysiological structures required to experience negative affect (with 90-100% likelihood). However, there are two different possibilities whether they perceive negative affect. It is more probable that the neurophysiological situation does not allow for conscious perception (with 66-99% likelihood) because of brain inhibitory mechanisms. There is also a less probable situation that livestock fetuses can experience negative affect (with 1-33% likelihood) arising from differences in the interpretation of the fetal electroencephalogram, observed responses to external stimuli and the possibility of fetal learning. Regarding methods to stun and kill livestock fetuses at slaughter (ToR4), sets of scenarios and respective actions take account of both the probable and less probable situation regarding fetal ability for conscious perception. Finally, information was collated on methods to establish the dam's gestational stage based on physical features of livestock fetuses (ToR5).

The importance of ‘awareness’ for understanding fetal pain

Our understanding of when the fetus can experience pain has been largely shaped by neuroanatomy. However, completion of the cortical nociceptive connections just after mid-gestation is only one part of the story. In addition to critically reviewing evidence for whether the fetus is ever awake or aware, and thus able to truly experience pain, we examine the role of endogenous neuro-inhibitors, such as adenosine and pregnanolone, produced within the feto-placental unit that contribute to fetal sleep states, and thus mediate suppression of fetal awareness. The uncritical view that the nature of presumed fetal pain perception can be assessed by reference to the prematurely born infant is challenged. Rigorously controlled studies of invasive procedures and analgesia in the fetus are required to clarify the impact of fetal nociception on postnatal pain sensitivity and neural development, and the potential benefits or harm of using analgesia in this unique setting.

The role of adenosine in regulation of cerebral blood flow during hypoxia in the near-term fetal sheep

The aim of this study was to determine in the near-term ovine fetus the role of adenosine in the basal regulation of cerebral blood flow and in the increases in cerebral blood flow in response to acute hypoxic insult. We measured cerebral blood flow in chronically instrumented fetal sheep (127-135 days gestation, term approximately 145 days) using laser Doppler flowmetry probes implanted in the parietal cortices. Hypoxia was administered for 30 min by lowering the ewe's inspired oxygen to 10-12 % during an infusion of either saline or theophylline, a non-specific adenosine receptor antagonist. The theophylline infusion was begun 30 min prior to and ended 30 min after the completion of the hypoxic insult. The administration of theophylline had no significant effect on cerebral blood flow during the baseline period. During control hypoxic periods, cerebral blood flow increased by approximately 45 %. During theophylline experiments, however, there was no significant increase in cerebral blood flow during hypoxia. In the control experiments, cerebral blood flow returned to baseline levels during the recovery period, while in the theophylline experiments cerebral blood flow fell below baseline levels. We conclude that, in the near-term ovine fetus, adenosine plays a minimal role in the regulation of basal cerebral blood flow. However, these data are strong evidence for the involvement of adenosine in increased fetal cerebral blood flow during an acute hypoxic insult. Finally, adenosine may also play an important role in the maintenance of fetal cerebral blood flow immediately following hypoxic insult.

Role of adenosine in regulation of brain temperature in fetal sheep

OBJECTIVE

The purpose of this study was to test adenosine's possible suppression of heat production by the ovine fetal brain during acute hypoxia.

STUDY DESIGN

Hypoxia was induced by occluding the umbilical cord for 5 minutes in 8 fetal sheep with and without an adenosine receptor blocker, theophylline, and fetal brain and core temperatures were recorded.

RESULTS

In 8 untreated fetuses, cord occlusion induced severe but reversible hypoxemia (decrease in carotid arterial PO (2) from 23 +/- 1 to 5 +/- 1 mm Hg (P <.01), a 2.3-fold increase in plasma adenosine, and an increase in body core temperature of 0.19 degrees C +/- 0.03 degrees C (P <.01), yet brain temperature remained constant. However, after cord occlusion with prior and continuing administration of theophylline, brain temperature did not increase as hypothesized but rather decreased, suggesting marked reductions in cerebral metabolic rate. This response occurred despite similar degrees of hypoxemia and similar increases in plasma adenosine and body core temperature.

CONCLUSION

We conclude that the temperature of the fetal ovine brain remains constant or decreases during severe reversible hypoxemia by mechanisms other than those dependent on adenosine.

Metabolic and endocrine responses to cold exposure in chronically incubated extrauterine goat fetuses

To investigate developmental aspects of metabolic and endocrine responses to cold exposure in fetuses, we conducted experiments on six goat fetuses, three aged 95-116 d of gestation (dGA; group I), and three aged 122-134 dGA (group II), using an extrauterine fetal incubation system that provided arterio-venous extracorporeal membrane oxygenation (A-V ECMO). The fetuses were cannulated via the umbilical vessels, and their blood gas exchange was totally supported by A-V ECMO, while they were maintained in an isothermal incubator containing artificial amniotic fluid. After confirming that fetuses were in metabolically stable condition in the extrauterine incubation system, fetal core temperature was lowered by 2 degrees C over 2 h by decreasing the temperature of incubating fluid from 39.5 degrees C. During and after cold exposure, fetal heart rate and arterial blood pressure remained unchanged. We observed significant increases in oxygen consumption and plasma concentrations of norepinephrine, epinephrine, adrenocorticotropic hormone, and cortisol in group II but not in group I fetuses. In addition, based on regression analysis, maximal changes of these parameters during cold exposure were linearly correlated with gestational age significantly, and the regression lines were found to intersect the x (gestational age) axis at around 98-106 dGA. These results suggest that metabolic and endocrine responses to cold exposure develop with gestational age in the goat fetus, the responses being manifested around 100 dGA.