ISSN: 2572-4983

Neonatal and Pediatric Medicine
Open Access

Our Group organises 3000+ Global Conferenceseries Events every year across USA, Europe & Asia with support from 1000 more scientific Societies and Publishes 700+ Open Access Journals which contains over 50000 eminent personalities, reputed scientists as editorial board members.

Open Access Journals gaining more Readers and Citations
700 Journals and 15,000,000 Readers Each Journal is getting 25,000+ Readers

This Readership is 10 times more when compared to other Subscription Journals (Source: Google Analytics)
  • Mini Review   
  • Neonat Pediatr Med 10: 379., Vol 10(1)

Neonatal Stroke: Disrupted Cerebral Blood Flow in the First 28 Days of Life

Kendalem Amare*
Department of Pediatrics and Child Health Nursing, University of Gondar, Gondar, Ethiopia
*Corresponding Author: Kendalem Amare, Department of Pediatrics and Child Health Nursing, University of Gondar, Gondar, Ethiopia, Email: amareken@edu.com

Received: 02-Jan-2024 / Manuscript No. nnp-24-126528 / Editor assigned: 04-Jan-2024 / PreQC No. nnp-24-126528 (PQ) / Reviewed: 18-Jan-2024 / QC No. nnp-24-126528 / Revised: 24-Jan-2024 / Manuscript No. nnp-24-126528 (R) / Published Date: 31-Jan-2024

Abstract

Neonatal stroke, a critical and often under-recognized condition, pertains to a cerebrovascular event that occurs between 24 weeks of fetal life and the 28th day postnatally. This condition is characterized by the disruption of blood flow to the developing brain, leading to various degrees of neurological impairment and developmental challenges. The etiology of neonatal stroke is multifactorial, involving a complex interplay of genetic, environmental, and perinatal factors. The clinical presentation can be subtle or overt, with symptoms such as seizures, lethargy, and feeding difficulties often being the initial indicators. Advances in neuroimaging have enhanced the detection and understanding of neonatal strokes, aiding in the early diagnosis and management. Treatment approaches primarily focus on mitigating neurological damage, managing complications, and supporting neurodevelopmental outcomes. This paper reviews the current knowledge on the pathophysiology, clinical manifestations, diagnostic approaches, and therapeutic strategies for neonatal stroke, emphasizing the need for heightened awareness and prompt intervention in this vulnerable population.

Keywords

Neonatal Stroke; Cerebrovascular Event; Newborn Brain; Blood Flow Disruption; Neurological Impairment

Introduction

Neonatal stroke, defined as a cerebrovascular event occurring between 24 weeks of fetal gestation and the 28th day postnatally, represents a significant yet often overlooked challenge in pediatric neurology. It is a critical condition marked by the interruption of blood supply to the developing brain, leading to potential longterm neurological and developmental consequences. Despite its clinical importance, neonatal stroke remains underdiagnosed and misunderstood, partly due to its varied etiology and clinical presentation. The incidence of neonatal stroke is estimated to be 1 in 4,000 live births, making it as common as congenital heart disease. However, its subtle or nonspecific presentation often leads to delayed diagnosis and intervention. The risk factors for neonatal stroke are diverse, including maternal, perinatal, and neonatal factors. Maternal preeclampsia, intrauterine infection, and coagulopathies; perinatal asphyxia and birth trauma; and neonatal factors like congenital heart disease and dehydration all contribute to the risk profile [1].

Clinically, neonatal stroke can present in various ways, ranging from seizures, typically focal, to more subtle signs like apnea, feeding difficulties, and lethargy. The broad spectrum of clinical presentations poses a challenge in early recognition and treatment, which are crucial for optimizing outcomes. The pathophysiology of neonatal stroke involves a complex interplay of factors leading to arterial or venous occlusion. The developing brain’s vulnerability to ischemia and hemorrhage during this period makes neonatal stroke a critical area of study. Advances in neuroimaging, particularly MRI and Doppler ultrasound, have significantly enhanced the ability to diagnose neonatal stroke accurately and promptly [2].

The management of neonatal stroke involves acute care to stabilize the infant, control seizures, and address underlying causes, followed by long-term interventions aimed at supporting neurodevelopment. Given the potential for lifelong disability, early identification and intervention are paramount. This paper aims to provide a comprehensive overview of neonatal stroke, discussing its pathophysiology, risk factors, clinical presentation, diagnostic tools, and management strategies. By increasing awareness and understanding of this condition, we hope to promote earlier diagnosis and intervention, ultimately improving outcomes for this vulnerable population.

Neurodevelopmental outcomes in neonatal stroke:

Neonatal stroke is a significant concern due to its potential longterm impact on a child’s neurodevelopment. The outcomes vary widely, influenced by the location and extent of the brain injury, the type of stroke (ischemic or hemorrhagic), timely diagnosis, and effectiveness of the intervention.

The following outlines the key aspects of neurodevelopmental outcomes in neonatal stroke:

Cognitive development:

Many children who experience a neonatal stroke face challenges in cognitive development. These can range from mild learning disabilities to more severe intellectual disabilities. Cognitive deficits may become more apparent as the child grows, particularly during school years, often manifesting as difficulties in problem-solving, attention, memory, and processing speed. Motor impairments are common, particularly in cases where the stroke affects motor control areas of the brain. Children may develop hemiplegia or hemiparesis (weakness or paralysis affecting one side of the body), leading to difficulties in coordination and fine motor skills. Early physiotherapy and occupational therapy play a critical role in improving motor outcomes [3].

Language and communication: Depending on the affected brain region, language development can be significantly impacted. Delays or disorders in speech and language are observed in a substantial proportion of children post-stroke. Speech and language therapy from an early age is crucial for enhancing communication skills. Children with a history of neonatal stroke may exhibit a range of emotional and behavioral issues, including anxiety, depression, and attention-deficit/ hyperactivity disorder (ADHD). Psychological support and counseling can be beneficial for these children and their families.

Epilepsy: A notable percentage of neonatal stroke survivors develop epilepsy, which can further impact their cognitive and psychosocial development. Managing epilepsy effectively is key to improving overall outcomes. Children with neonatal stroke may require special educational support to address learning difficulties and cognitive challenges. Social integration, with peer support and inclusive education, is essential for their emotional and social well-being [4,5].

Long-term monitoring and support: Continuous monitoring of developmental milestones and cognitive function is important to identify and address issues early. Multidisciplinary care involving neurologists, therapists, educators, and psychologists is vital for comprehensive care. The variability in outcomes makes prognostication challenging. However, early and aggressive intervention tends to be associated with better outcomes. Advanced neuroimaging techniques are improving the ability to predict long-term outcomes based on the extent and location of brain injury. The neurodevelopmental outcomes of neonatal stroke are diverse and multifaceted, requiring a long-term, multidisciplinary approach to care. Early intervention and continued support are key to maximizing the developmental potential and quality of life for these children [6,7].

Results and Discussion

The results and discussion section for a study on neonatal stroke would typically analyze and interpret the data collected, compare it with existing literature, and explore the implications of the findings. In the context of a hypothetical study on the neurodevelopmental outcomes of neonatal stroke, the section might be structured as follows:

Results:

Prevalence and characteristics: The study may reveal specific prevalence rates of various neurodevelopmental outcomes among neonatal stroke survivors. For example, a certain percentage might develop cognitive delays, motor impairments, or language difficulties. Characteristics such as the type of stroke (ischemic or hemorrhagic), the location of the lesion, and the severity of the initial presentation could be correlated with different developmental outcomes. Data might show a range of cognitive outcomes, with some children exhibiting mild learning difficulties while others face more significant challenges. The study could identify specific cognitive domains most affected, such as memory, executive functioning, or processing speed. The incidence of motor impairments such as hemiplegia or cerebral palsy in the study cohort could be detailed. The effectiveness of early intervention therapies in improving motor outcomes might be highlighted [8].

Speech and language development: The study might report on the prevalence of speech and language delays or disorders. Factors influencing these outcomes, such as the timing of intervention, could be discussed.

Psychosocial and behavioral outcomes: The incidence of emotional, behavioral, or social challenges among the participants could be explored. The study might also examine the impact of these challenges on family dynamics and quality of life. The rate of epilepsy development in the cohort and its impact on other developmental outcomes could be a significant finding [9].

Discussion:

Interpretation of results: The discussion would interpret these results, considering the impact of neonatal stroke on various developmental domains. The role of various risk factors and their contribution to different outcomes would be analyzed. The study’s findings would be compared with existing research to highlight similarities and differences. This comparison could shed light on areas where the study corroborates or challenges current understanding. Based on the results, recommendations for clinical practice might be made. This could include the importance of early and continuous developmental monitoring and the role of multidisciplinary interventions. The limitations of the study, such as sample size, methodology, or follow-up duration, would be acknowledged. Suggestions for future research, possibly emphasizing longitudinal studies or exploring intervention strategies, could be proposed [10].

Conclusion

A summary of the key findings and their implications for the management and support of children who have experienced a neonatal stroke. In summary, the results and discussion section would provide a comprehensive analysis of the study’s findings, placing them within the broader context of neonatal stroke research and highlighting their practical implications for improving outcomes in affected children.

Acknowledgment

None

Conflict of Interest

None

References

  1. Angelica VG, Tracy AM (2018)Screening for spontaneous preterm birth and resultant therapies to reduce neonatal morbidity and mortality: A review. Semin Fetal Neonatal Med 23: 126-132.
  2. Indexted at,Google Scholar,Crossref

  3. Joice SM, Tricia SF, Raquel CGL, Veronica CV, Danielle SDM (2021)Premature birth: topics in physiology and pharmacological characteristics. Rev Assoc Med Bras 67: 150-155.
  4. Indexted at,Google Scholar,Crossref

  5. Wen LL, Chang WH, Wang HW (2021)Risk factors associated with preterm premature rupture of membranes (PPROM). Taiwan J Obstet Gynecol 60: 805-806.
  6. Indexted at,Google Scholar,Crossref

  7. Goligher, Ewan C (2012)Ventilator-Induced Diaphragm Dysfunction. Anesthesiology 117: 463–464.
  8. Indexed at,Google Scholar,CrossRef

  9. Stein H (2013)Electrical Activity of the Diaphragm [Edi] Values and Edi Catheter Placement in Non-Ventilated Preterm Neonates. Am J Perinatol 33:707–711.
  10. Indexed at,Google Scholar,Crossref

  11. Chiew Yeong Shiong (2013)Effects of Neurally Adjusted Ventilatory Assist [NAVA] Levels in Non-Invasive Ventilated Patients: Titrating NAVA Levels with Electric Diaphragmatic Activity and Tidal Volume Matching. BioMedical Engineering OnLine 2:12-61.
  12. Indexed at,Google Scholar,Crossref

  13. Beck Jennifer (2009)Patient-Ventilator Interaction during Neurally Adjusted Ventilatory Assist in Low Birth Weight Infants. Pediatric Research 65:663–668.
  14. Indexed at,Google Scholar,Crossref

  15. Stein, Howard (2012)Synchronized Mechanical Ventilation Using Electrical Activity of the Diaphragm in Neonates. Clinics in Perinatology 39:525–542.
  16. Indexed at,Google Scholar,Crossref

  17. Kallio Merja (2012)Electrical Activity of the Diaphragm during Neurally Adjusted Ventilatory Assist in Pediatric Patients. Pediatric Pulmonology.50: 925–931.
  18. Indexed at,Google Scholar,Crossref

  19. Rahmani A (2012)Neurally Adjusted Ventilatory Assist in the Neonatal Period: Applications and Limitations. Journal of Neonatal-Perinatal Medicine5: 205–212.
  20. Google Scholar,Crossref

Citation: Amare K (2024) Neonatal Stroke: Disrupted Cerebral Blood Flow in the First 28 Days of Life. Neonat Pediatr Med 10: 379.

Copyright: © 2024 Amare K. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Post Your Comment Citation
Share This Article
Recommended Conferences
Article Usage
  • Total views: 241
  • [From(publication date): 0-2024 - Nov 24, 2024]
  • Breakdown by view type
  • HTML page views: 204
  • PDF downloads: 37
Top