Advances in scarless foetal wound healing and prospects for scar reduction in adults.

Healing after mammalian skin injury involves the interaction between numerous cellular constituents and regulatory factors, which together form three overlapping phases: an inflammatory response, a proliferation phase and a remodelling phase. Any slight variation in these three stages can substantially alter the healing process and resultant production of scars. Of particular significance are the mechanisms responsible for the scar-free phenomenon observed in the foetus. Uncovering such mechanisms would offer great expectations in the treatment of scars and therefore represents an important area of investigation. In this review, we provide a comprehensive summary of studies on injury-induced skin regeneration within the foetus. The information contained in these studies provides an opportunity for new insights into the treatment of clinical scars based on the cellular and molecular processes involved.

Secondary maternal-fetal consequences to electrical injury: A literature review.

Electrical injuries can occur in pregnant women but currently their incidence is not completely known. Notwithstanding, those represent clinical important events such maternal and fetal death, which can be avoided if properly managed. The objective of this paper is to describe the results of electrical injury (high and low voltage), in pregnant women in scientific reports. A systematic search was performed with keywords "electrical injuries", "lightning injuries", "lightning strike", "pregnant women" and "pregnancy", using the databases: MedLine, Scielo, Lilacs, Clinical key, Web of Science, Scopus, Springer, Science Direct, Embase and Medic Latina. Filters like language, time, design and availability of text were not used. Descriptive analyses were carried out for variables such as maternal-fetal consequences, voltage and type of exposure, based on the reports identified. From the total 74 cases identified, 71.1% survived after the exposition. From the total live-births 28.6% did not show any alteration, 7.1% presented maceration and burns, while 64.3% had another outcome. Electric injury leads to fetal compromise and death in exposed pregnant women, mainly in the first hours after the injury. However, monitoring should be continued for the risk of complications such as placenta abruption, oligohydramnios and fetal distress. It is possible an underreporting of these events.

Traumatic injury in female Drosophila melanogaster affects the development and induces behavioral abnormalities in the offspring.

Traumatic injury (TI) during pregnancy increases the risk for developing neurological disorders in the infants. These disorders are a major concern for the well-being of children born after TI during pregnancy. TI during pregnancy may result in preterm labor and delivery, abruptio placentae, and/or fetomaternal hemorrhage. Drosophila melanogaster (fruit fly) is a widely used model to study brain and behavioral disorders in humans. In this study, we analyzed the effects of TI to female fruit flies on the development timing of larvae, social interaction and the behavior of offspring flies. TI to the female flies was found to affect the development of larvae and the behavior of offspring flies. There was a significant increase in the length of larvae delivered by traumatically injured maternal flies as compared to larvae from control maternal flies (without TI). The pupae formation from larvae, and the metamorphosis of pupae to the first generation of flies were faster in the TI group than the control group. Negative geotaxis and distance of the fly to its nearest neighbor are parameters of behavioral assessment in fruit flies. Negative geotaxis significantly decreased in the first generation of both male (p = 0.0021) and female (p = 0.0426) flies. The distance between the first generation of flies to its nearest neighbor was shorter in both male and female offspring flies in the TI group as compared to control group flies. These results indicate that TI to the female flies affected the development of larvae and resulted in early delivery, impaired social interaction and behavioral alterations in the offspring.

Effects of Maternal Sildenafil Treatment on Vascular Function in Growth-Restricted Fetal Sheep.

Objective- The objective of this study was to investigate the effect of intravenous maternal sildenafil citrate (SC) administration on vascular function in growth-restricted fetal sheep. Approach and Results- Fetal growth restriction (FGR) results in cardiovascular adaptations that redistribute cardiac output to optimize suboptimal intrauterine conditions. These adaptations result in structural and functional cardiovascular changes, which may underlie postnatal neurological and cardiovascular sequelae. Evidence suggests SC, a potent vasodilator, may improve FGR. In contrast, recent clinical evidence suggests potential for adverse fetal consequence. Currently, there is limited data on SC effects in the developing fetus. We hypothesized that SC in utero would improve vascular development and function in an ovine model of FGR. Preterm lambs (0.6 gestation) underwent sterile surgery for single umbilical artery ligation or sham (control, appropriately grown) surgery to replicate FGR. Ewes received continuous intravenous SC (36 mg/24 h) or saline from surgery until 0.83 gestation. Fetuses were delivered and immediately euthanized for collection of femoral and middle cerebral artery vessels. Vessel function was assessed via in vitro wire myography. SC exacerbated growth restriction in growth-restricted fetuses and resulted in endothelial dysfunction in the cerebral and femoral vasculature, irrespective of growth status. Dysfunction in the cerebral circulation is endothelial, whereas smooth muscle in the periphery is the origin of the deficit. Conclusions- SC crosses the placenta and alters key fetal vascular development. Extensive studies are required to investigate the effects of SC on fetal development to address safety before additional use of SC as a treatment.

Early recognition and management of fetal head trauma with massive subgaleal hemorrhage.

Non-obstetrical fetal head injury is an unusual clinical event. While multiple case reports describe motor vehicle collisions resulting in intrauterine fetal skull fractures, management of these injuries has not been emphasized. We report a case of a depressed fetal skull fracture with massive subgaleal and subperiosteal hemorrhage requiring neurosurgical intervention with good clinical outcomes for both mother and infant dyad.

Fetal gunshot brain injury leading to late postnatal hydrocephalus.

A male fetus was delivered by emergent caesarean section after a term pregnant mother was caught in crossfire and sustained gunshot injury to her abdomen. Examination of the infant was unremarkable except for a small laceration of the scalp at the anterior fontanelle. Skull radiography showed a dense bullet shaped opacity in the brain. He was managed conservatively and was discharged home on full feeds with normal neurological examination. He developed seizures and progressive hydrocephalus, and underwent a ventriculoperitoneal (VP) shunt placement at 5 weeks of age. At 13 months of age the bullet was removed. To our knowledge this is the first report of fetal brain injury with intact bullet in the brain with survival. This case provides the context for a discussion about factors that contribute to survival and favorable prognosis of infants with fetal penetrating gunshot brain injury.

Learning from regeneration research organisms: The circuitous road to scar free wound healing.

The skin is the largest organ in the body and plays multiple essential roles ranging from regulating temperature, preventing infection and ultimately defining who we are physically. It is a highly dynamic organ that constantly replaces the outermost cells throughout life. However, when faced with a major injury, human skin cannot restore a significant lesion to its original functionality, instead a reparative scar is formed. In contrast to this, many other species have the unique ability to regenerate full thickness skin without formation of scar tissue. Here we review recent advances in the field that shed light on how the skin cells in regenerative species react to injury to prevent scar formation versus scar forming humans.

Neonatal erythropoietin mitigates impaired gait, social interaction and diffusion tensor imaging abnormalities in a rat model of prenatal brain injury.

Children who are born preterm are at risk for encephalopathy of prematurity, a leading cause of cerebral palsy, cognitive delay and behavioral disorders. Current interventions are limited and none have been shown to reverse cognitive and behavioral impairments, a primary determinant of poor quality of life for these children. Moreover, the mechanisms of perinatal brain injury that result in functional deficits and imaging abnormalities in the mature brain are poorly defined, limiting the potential to target interventions to those who may benefit most. To determine whether impairments are reversible after a prenatal insult, we investigated a spectrum of functional deficits and diffusion tensor imaging (DTI) abnormalities in young adult animals. We hypothesized that prenatal transient systemic hypoxia-ischemia (TSHI) would induce multiple functional deficits concomitant with reduced microstructural white and gray matter integrity, and tested whether these abnormalities could be ameliorated using postnatal erythropoietin (EPO), an emerging neurorestorative intervention. On embryonic day 18 uterine arteries were transiently occluded for 60min via laparotomy. Shams underwent anesthesia and laparotomy for 60min. Pups were born and TSHI pups were randomized to receive EPO or vehicle via intraperitoneal injection on postnatal days 1 to 5. Gait, social interaction, olfaction and open field testing was performed from postnatal day 25-35 before brains underwent ex vivo DTI to measure fractional anisotropy, axial diffusivity and radial diffusivity. Prenatal TSHI injury causes hyperactivity, impaired gait and poor social interaction in young adult rats that mimic the spectrum of deficits observed in children born preterm. Collectively, these data show for the first time in a model of encephalopathy of prematurity that postnatal EPO treatment mitigates impairments in social interaction, in addition to gait deficits. EPO also normalizes TSHI-induced microstructural abnormalities in fractional anisotropy and radial diffusivity in multiple regions, consistent with improved structural integrity and recovery of myelination. Taken together, these results show behavioral and memory deficits from perinatal brain injury are reversible. Furthermore, resolution of DTI abnormalities may predict responsiveness to emerging interventions, and serve as a biomarker of CNS injury and recovery.

Angiogenesis and wound repair: when enough is enough.

All animals heal, and the ability to heal is requisite for human health. One aspect of repair that has always been considered to be essential for adequate healing is the creation of a new vasculature via angiogenesis. As adult skin wounds heal, a period of rapid and robust capillary growth creates a vascular bed that has many fold more capillaries than does normal tissue. Over time, most of the newly formed capillaries regress, resulting in a final vascular density similar to that of normal skin. Certainly, new capillaries are necessary to bring nutrients, immune cells, and oxygen to healing wounds. Yet, the presumed functional importance of an overabundance of capillaries has recently been challenged, creating questions about whether excess capillary growth is truly necessary for healing. In particular, studies of wounds that heal exceptionally quickly and with less scar formation, such as those in fetal skin and oral mucosa, show that these tissues heal with a reduced angiogenic burst composed of more mature vessels that provide better oxygenation. The level of angiogenesis in wounds often correlates with the inflammatory response, largely because inflammatory cells produce an abundance of proangiogenic mediators. Both the selective reduction of inflammation and the selective reduction of angiogenesis have now been suggested as ways to improve scarring. These concepts link excessive inflammation and the production of a dense but poorly perfused capillary bed to inferior healing outcomes.

Prenatal ischemia deteriorates white matter, brain organization, and function: implications for prematurity and cerebral palsy.

Cerebral palsy (CP) describes a group of neurodevelopmental disorders of posture and movement that are frequently associated with sensory, behavioral, and cognitive impairments. The clinical picture of CP has changed with improved neonatal care over the past few decades, resulting in higher survival rates of infants born very preterm. Children born preterm seem particularly vulnerable to perinatal hypoxia-ischemia insults at birth. Animal models of CP are crucial for elucidating underlying mechanisms and for development of strategies of neuroprotection and remediation. Most animal models of CP are based on hypoxia-ischemia around the time of birth. In this review, we focus on alterations of brain organization and functions, especially sensorimotor changes, induced by prenatal ischemia in rodents and rabbits, and relate these alterations to neurodevelopmental disorders found in preterm children. We also discuss recent literature that addresses the relationship between neural and myelin plasticity, as well as possible contributions of white matter injury to the emergence of brain dysfunctions induced by prenatal ischemia.

[ELECTRICAL ACTIVITY OF THE NEOCORTEX IN ADULT RATS AFTER PRENATAL HYPOXIA AND IN EPILEPSY MODEL].

Changes in electrical activity of neocortex after prenatal hypoxia (day 14 of embryogenesis - E14, 7 % 02 for 3 hours) and these combined with intracortical microinjection of epileptogenic 4-aminopyridine (4-AP) have been studied in adult rats. We analyzed the frequency-time parameters of electrocorticogram (ECoG) during sleep and wakefulness as well as spike-wave discharge (SWD) in 4-AP-induced epileptiform model. The results showed that in rats subjected to prenatal hypoxia the theta rhythm had a lower frequency and sleep spindles were characterized by lower spectral power in low-frequency domain in comparison with the control group. In rats with prenatal pathology delayed onset of epileptiform activi- ty and altered frequency distribution of the spectral power of 4-AP-induced SWD were revealed.

Prenatal Hypoxia Ischemia Increases Male Rat Sexual Behavior.

INTRODUCTION: Research consistently indicates an association between prenatal hypoxia-ischemia (HI) and mortality and chronic neurological diseases in newborns. HI can cause permanent effects, including mental retardation, motor impairment, learning disabilities, epilepsy, and cerebral palsy. Moreover, little is known about the relationship between HI and sexual behavior. AIMS: The aims of this study are to examine whether HI is associated with changes in sexual behavior. METHODS: HI was induced by clamping the uterine arteries of pregnant rats. The arteries were clamped for 45 minutes on the 18th day of gestation (HI group). Shams received laparotomy and anesthesia only. Pups were born at term. At 90 days of age, sexual behavior was evaluated. Statistical analysis was performed using two-way analysis of variance and post hoc Bonferonni correction. MAIN OUTCOME MEASURES: The main outcome measures of sexual response were standard sexual behavior, homosexual behavior, and sexual attempt on nonreceptive females. RESULTS: The stimulatory effect of HI on male rat sexual behavior has been shown in various experimental models; these animals showed reduced mount, intromission and ejaculation latencies; increased copulatory efficiency; and homosexual mounting. Additionally, there was an increase in fighting in trying to mount an unreceptive female. CONCLUSION: Our results indicate that HI had a long-term effect on sexual behavior despite exhibiting motor skill impairment. Accordingly, injuries during the fetal period may cause behavioral problems in adulthood.

Regenerative healing, scar-free healing and scar formation across the species: current concepts and future perspectives.

All species have evolved mechanisms of repair to restore tissue function following injury. Skin scarring is an inevitable and permanent endpoint for many postnatal organisms except for non-amniote vertebrates such as amphibians, which are capable of tissue regeneration. Furthermore, mammalian foetuses through mid-gestation are capable of rapid wound repair in the absence of scar formation. Notably, excessive cutaneous scar formation, such as hypertrophic and keloid scars, is a species limited clinical entity as it occurs only in humans, although wounds on the distal limbs of horses are also prone to heal with fibroproliferative pathology known as equine exuberant granulation tissue. Currently, there are no reliable treatment options to eradicate or prevent scarring in humans and vertebrates. The limited number of vertebrate models for either hypertrophic or keloid scarring has been an impediment to mechanistic studies of these diseases and the development of therapies. In this viewpoint essay, we highlight the current concepts of regenerative, scar-free and scar-forming healing compared across a number of species and speculate on areas for future research. Furthermore, in-depth investigative research into the mechanisms of scarless repair may allow for the development of improved animal models and novel targets for scar prevention. As the ability to heal in both a scarless manner and propensity for healing with excessive scar formation is highly species dependent, understanding similarities and differences in healing across species as it relates to the regenerative process may hold the key to improve scarring and guide translational wound-healing studies.

Microglia toxicity in preterm brain injury.

Microglia are the resident phagocytic cells of the central nervous system. During brain development they are also imperative for apoptosis of excessive neurons, synaptic pruning, phagocytosis of debris and maintaining brain homeostasis. Brain damage results in a fast and dynamic microglia reaction, which can influence the extent and distribution of subsequent neuronal dysfunction. As a consequence, microglia responses can promote tissue protection and repair following brain injury, or become detrimental for the tissue integrity and functionality. In this review, we will describe microglia responses in the human developing brain in association with injury, with particular focus on the preterm infant. We also explore microglia responses and mechanisms of microglia toxicity in animal models of preterm white matter injury and in vitro primary microglia cell culture experiments.

Fetal intracranial injuries following motor vehicle accidents with airbag deployment.

The effects of airbag deployment in motor vehicle accidents (MVA) on the fetus are poorly understood. A 22-year-old woman at 24 weeks of gestation collided with a telephone pole while driving. She was restrained and an airbag deployed. Although she had no major injuries, she experienced decreased fetal movements. Fetal heart rate (FHR) monitoring revealed loss of variability without any evidence of abruptio placentae, and 4 days later, the variability spontaneously recovered. Two weeks after the MVA, ultrasonography showed unilateral ventricular dilatation suggestive of fetal brain injury. Magnetic resonance imaging revealed subdural hematoma, intraventricular hemorrhage and cystic lesions, interpreted as indirect (hypoxic-ischemic) and direct (hemorrhagic) intracranial injuries. After MVA with airbag deployment, FHR monitoring can show a transient loss of variability, which may precede the appearance of fetal brain injury.

Pathophysiological mechanisms of impaired limb use and repair strategies for motor systems after unilateral injury of the developing brain.

The corticospinal tract (CST) is important for limb control. In humans, it begins developing prenatally but CST connections do not have a mature pattern until about 6 months of age and its capacity to evoke muscle contraction does not mature until mid-adolescence. An initially bilateral projection is subsequently refined, so that most ipsilateral CST connections are eliminated. Unilateral brain damage during refinement leads to bilateral developmental impairments. The damaged side develops sparse and weak contralateral spinal connections and the non-involved hemisphere maintains its ipsilateral projection to develop an aberrant bilateral spinal projection. In a kitten model of unilateral spastic cerebral palsy, we replicate key features of the CST circuit changes: robust bilateral CST projections from the non-involved hemisphere, sparse contralateral connections from the affected hemisphere, and motor impairments. We discuss the role of activity-dependent synaptic competition in development of bilateral CSTs and consider several experimental strategies for restoring a more normal pattern of CST connections from the damaged and non-involved sides. We highlight recent results stressing the importance of combined repair of CST axons, restoration of a more normal motor cortex motor representation, and key involvement of spinal cholinergic interneurons in restoring skilled motor function.

Transmitting biological effects of stress in utero: implications for mother and offspring.

The developing foetus makes adaptations to an adverse in utero environment which may lead to permanent changes in structure and physiology, thus 'programming' the foetus to risk of ill health in later life. Epidemiological studies have shown associations between low birth weight, a surrogate marker of an adverse intrauterine environment, and a range of diseases in adult life including cardiometabolic and psychiatric disease. These associations do not apply exclusively to low birth weight babies but also to newborns within the normal birth weight range. Early life stress, including stressors in the prenatal and early postnatal period, is a key factor that can have long-term effects on offspring health. Animal studies show this is mediated through changes in the maternal and foetal hypothalamic-pituitary-adrenal axes resulting in foetal exposure to excess glucocorticoids. Data in humans are more limited but support that the biological effects of stress in utero may be transmitted through changes in glucocorticoid action or metabolism. Common contemporary physical and social stressors of maternal obesity and socio-economic deprivation impact on the maternal response to pregnancy and the prevailing hormonal milieu that the developing foetus will be exposed to. Prenatal stress may also be compounded by early postnatal stresses such as childhood maltreatment with resultant adverse effects for the offspring. Understanding of the mechanisms whereby these stressors are transmitted from mother to foetus will not only improve our knowledge of normal foetal development but will also help identify novel pathways for early intervention either in the periconceptional, pregnancy or the early postpartum period.

Spontaneous seizures in a rat model of multiple prenatal freeze lesioning.

Focal cortical dysplasia (FCD) is an important cause of intractable epilepsy. Previous rat studies have utilized freeze lesioning of neonatal animals to model FCD; however, such models are unable to demonstrate spontaneous seizures without seizure-provoking events. Therefore, we created an animal model with multiple FCD, produced during embryonic development, and observed whether spontaneous seizures occurred. Furthermore, we examined the relationship between FCD and epileptogenesis using immunohistochemistry. At 18 days postconception, a frozen metal probe was placed bilaterally on the scalps of Sprague-Dawley rat embryos through the uterus wall to produce multiple FCD. Electroencephalogram (EEG) and video recording were performed from postnatal day (P) 35 to P77. Brain tissues were examined immunohistochemically at P28 and P78 using semiquantitative densitometry. Eleven of 16 rats (68.8%) showed spontaneous seizures arising in the hippocampus from P47. Movement cessation followed by sniffing and mastication, culminating in wet-dog shaking, was seen during the hippocampal EEG discharges. FCD was observed in the bilateral frontoparietal lobes. The expression levels of N-methyl-d-aspartate receptor (NMDAR) subunits 1, 2A, 2B, the glutamate/aspartate transporter and the glial glutamate transporter 1 (GLT1) at FCD sites were increased at P28 and P78. There were no major histological abnormalities in the hippocampi compared with those in the cortex. However, the expression levels of NMDAR 2A and 2B were increased at P28. Levels of NMDAR1, 2A and 2B, the glutamate/aspartate transporter and GLT1 were also increased at P78. We created an animal model showing spontaneous seizures without a provoking event except for the existence of cortical dysplasia, and without a genetic or general systematic cause like MAM injection or irradiation. The seizures resembled human temporal lobe epilepsy both clinically and on EEG. Alterations in the levels of glutamatergic and GABAergic receptors were investigated during growth. This model should enable better clarification of the mechanisms underlying the development of human epilepsy.

[Effects of repeated short-term immobilization stress on plastisity of brain cortical division and cognition in adult rats with normal and disturbed embryogenesis].

The aim of the work was the analysis of the changes in a number of labile synaptopodin-positi- ve dendritic spines in parietal cortex and the CA1 field of the hippocampus, which characterize plasticity of intracellular interaction, and of the memorization after short-term repeated immobili- zation stress (daily for 5 minutes, 10 days), both in control rats and in rats subjected to prenatal hypoxia (E14, 7% of O2, 3 hours). There were observed deterioration of short-term and long-term memory, decrease in number labile spines in the CA1 field of the hippocampus (for 17.3 ± 10.4%; p ≤ 0.05) and their increase in a molecular layer of brain parietal cortex (for 36.9 ± 9.2%) at the adult rats with normal embryogenesis after immobilization stress in comparison with control intact animals. At the rats subjected to a prenatal hypoxia, regardless of that, they were ex- posed to an immobilized stress at an adult stage or not, was noted both violation of short-term and long-term memory, and decrease in number labile spines in the CA1 field of the hippocampus (for 22.9 ± 10.5%) and parietal cortex (for 28.1 ± 9.3%). The obtained data allow to conclude that the increase of plasticity providing adaptive behavior of animals, takes place in neocortical neuronal networks as a reply to a short-term repeating stress only at normal brain formation during embryo- genesis, while, violation of embryogenesis leads to decrease in plasticity and adaptive opportuni- ties of the nervous system during further ontogenesis.