Noninvasive intracranial pressure monitoring throughout brain compliance guiding a ventriculoperitoneal shunt replacement in hydrocephalus-case report.

INTRODUCTION: Ventriculoperitoneal (VP) shunt is the primary therapy for hydrocephalus in children; however, this technique is amenable to malfunctions, which could be detected through an assessment of clinical signs and imaging results. Furthermore, early detection can prevent patient deterioration and guide clinical and surgical treatment. CASE PRESENTATION: A 5-year-old female with a premedical history of neonatal IVH, secondary hydrocephalus, multiple VP shunts revisions, and slit ventricle syndrome was evaluated using a noninvasive intracranial pressure monitor device at the early stages of the clinical symptoms, evidencing increased intracranial pressure and poor brain compliance. Serial MRI images demonstrated a slight ventricular enlargement, leading to the use of a gravitational VP shunt, promoting progressive improvement. On the follow-up visits, we used the noninvasive ICP monitoring device to guide the shunt adjustments until symptom resolution. Furthermore, the patient has been asymptomatic for the past 3 years without requiring new shunt revisions. DISCUSSION: Slit ventricle syndrome and VP shunt dysfunctions are challenging diagnoses for the neurosurgeon. The noninvasive intracranial monitoring has allowed a closer follow-up assisting early assessment of brain compliance changes related to a patient's symptomatology. Furthermore, this technique has high sensitivity and specificity in detecting alterations in the intracranial pressure, serving as a guide for the adjustments of programmable VP shunts, which may improve the patient's quality of life. CONCLUSION: Noninvasive ICP monitoring may lead to a less invasive assessment of patients with slit ventricle syndrome and could be used as a guide for adjustments of programmable shunts.

Torque Teno virus DNA is found in the intracranial aneurysm wall-Is there a causative role?

Objective: Torque Teno virus (TTV) is a recently discovered virus with high prevalence worldwide, that has been associated with vascular diseases. The aim of this study is to investigate the prevalence of TTV molecular DNA in the intracranial aneurysm (IA) artery walls. Method: Samples of IA walls were collected after microsurgical clipping from 35 patients with IA (22 ruptured/13 unruptured cases). The samples were submitted to molecular DNA extraction using the EasyMag automatized extractor and performed with Qiagen DNA extraction Minikit 250. The samples underwent PCR examination with primers for ß-globin as internal control using the Nanodrop ® 2000 spectrophotometer. A quantitative (real-time) PCR with TTV-specific primers was performed. Clinical and radiological data of patients included was collected. Results: TTV was detected in 15 (42.85%) cases, being 10 (45.4%) ruptured and 5 (38.4%) unruptured (p = 0.732) lesions. Multiple IAs accounted for 14 (40%) cases. Five cases (17.2%) had TTV+ and multiple aneurysms (p = 0.73). Association between presence of virus and aneurysm rupture was not statistically significant (p = 0.96). Conclusion: This study demonstrated a relatively high prevalence of viral DNA in the walls of IAs. This is the first study to identify the presence of TTV DNA in IA's samples, which was found more often in ruptured lesions. This is an exploratory study, therefore, larger studies are required to clarify the relationships between inflammation, viral infection, IA formation and rupture.

Spina bifida folate fortification in Brazil, update 2022: a cross-sectional study.

INTRODUCTION: Despite improving maternal-child indicators in Brazil, congenital malformations are still the second cause of mortality in the first years of life. This work aims to compare statistical data before and after flour fortification with folic acid (FA) in Brazil. METHODS: A cross-sectional Brazilian-population-based study compares the spina bifida (SB) rates pre- and post-fortification of the flour with folate. Data collected from the public database of the Live Birth Information System (SINASC/SUS) was performed. The period 1999-2004 (pre-fortification) was compared with 2005-2010 (post-maize and wheat fortification with FA), and another analysis comparing 2005-2010 and 2011-2020 (cassava flour fortification) was performed. The estimator was the prevalence ratio (PRR); the confidence interval selected was 95%. We used a random effects analysis model and inverse variance. RESULTS: The review showed a tendency to decrease the PRR after flour fortification; however, there is no statistical significance between studies. DATASUS data analysis comparing 5 years before and 5 years after mandatory maize and wheat flour fortification demonstrated a rate ratio of 1.05 (95% CI 0.99-1.1; p = 0.075). Furthermore, comparing 10 years after additional cassava flour folate fortification, the rate ratio increased to 1.4 (95% CI 1.34-1.45; p < 0.01). CONCLUSION: This study demonstrated an increase in SB after FA fortification. Possible explanations rely on national registry improvement, not fortified staple food, or further unidentified causes. Moreover, suggestions can be made for creating a mandatory registry for malformations, inspecting the concentrations of FA in the flour, and fortifying all food.

Three-Dimensional Printing in Minimally Invasive Cardiac Surgery: Optimizing Surgical Planning and Education with Life-Like Models.

Over recent years, the surgical community has demonstrated a growing interest in imaging advancements that enable more detailed and accurate preoperative diagnoses. Alongside with traditional imaging methods, three-dimensional (3-D) printing emerged as an attractive tool to complement pathology assessment and surgical planning. Minimally invasive cardiac surgery, with its wide range of challenging procedures and innovative techniques, represents an ideal territory for testing its precision, efficacy, and clinical impact. This review summarizes the available literature on 3-D printing usefulness in minimally invasive cardiac surgery, illustrated with images from a selected surgical case. As data collected demonstrates, life-like models may be a valuable adjunct tool in surgical learning, preoperative planning, and simulation, potentially adding safety to the procedure and contributing to better outcomes.

Three-Dimensional Printing in Minimally Invasive Cardiac Surgery: Optimizing Surgical Planning and Education with Life-Like Models

Abstract Over recent years, the surgical community has demonstrated a growing interest in imaging advancements that enable more detailed and accurate preoperative diagnoses. Alongside with traditional imaging methods, three-dimensional (3-D) printing emerged as an attractive tool to complement pathology assessment and surgical planning. Minimally invasive cardiac surgery, with its wide range of challenging procedures and innovative techniques, represents an ideal territory for testing its precision, efficacy, and clinical impact. This review summarizes the available literature on 3-D printing usefulness in minimally invasive cardiac surgery, illustrated with images from a selected surgical case. As data collected demonstrates, life-like models may be a valuable adjunct tool in surgical learning, preoperative planning, and simulation, potentially adding safety to the procedure and contributing to better outcomes.

The Potential Applications of Augmented Reality in Fetoscopic Surgery for Antenatal Treatment of Myelomeningocele.

OBJECTIVE: To develop a preoperative planning method using augmented reality (AR) of a specific surgical procedure: fetoscopy for myelomeningocele repair. METHODS: Imaging data were acquired of a pregnant woman at 27 weeks of gestation whose fetus was diagnosed with myelomeningocele. The patient was identified as a candidate for fetoscopic repair of the spine defect, and an AR application for mobile device simulation was developed. The virtual customized model was created by analysis of the presurgical magnetic resonance imaging. A real-time AR interface was developed by using an application that enhanced the anatomical aspects of both mother and fetus. RESULTS: A virtual model for planning fetoscopy repair for myelomeningocele was developed. Preoperative and postoperative procedures were successfully carried out, emphasizing the beneficial role of the AR application. The use of the AR model allowed the multidisciplinary team to engage in discussion to determine the appropriate surgical approach. It also allowed a clearer explanation of the procedure to the parents enabling a better understanding of the parents regarding specifics characteristics of their baby's spine defect. CONCLUSIONS: This new preoperative platform using a virtual model represents an important tool to improve patient's comprehension, multidisciplinary discussion, and surgical planning. In addition, it can be used worldwide as a teaching tool in the fetal surgery field.

The historic evolution of intracranial pressure and cerebrospinal fluid pulse pressure concepts: Two centuries of challenges.

BACKGROUND: There is a consensus on the importance of monitoring intracranial pressure (ICP) during neurosurgery, and this monitoring reduces mortality during procedures. Current knowledge of ICP and cerebrospinal fluid pulse pressure has been built thanks to more than two centuries of research on brain dynamics. METHODS: Articles and books were selected using the descriptors "ICP," "cerebrospinal fluid pulse," "monitoring," "Monro-Kellie doctrine," and "ICP waveform" in electronic databases PubMed, Lilacs, Science Direct, and EMBASE. RESULTS: Several anatomists and physiologists have helped clarify the patterns of intracranial volumes under normal and pathological conditions. Monro-Kellie doctrine was an important step in a story that is reconstructed in this article. Through documentary research, we report the contribution of important medical figures, such as Monro, Kellie, Abercrombie, Burrows, Cushing, Langfitt, Marmarou, and other physiologists and anatomists who left their marks on the history of Medicine. CONCLUSION: Understanding intracranial dynamics is an unfinished historical construction. Current knowledge is the result of two centuries of research that began with the investigations of Alexander Monro secundus.

Preoperative Planning Modalities for Meningoencephalocele: New Proof of Concept.

OBJECTIVE: Late surgical correction of meningoencephalocele is a rare scenario that remains challenging for surgeons. Three-dimensional models can mimic the correct anatomical relationships, and technological systems have brought advances to medicine. This study aims to present a novel preoperative planning modality that combines augmented reality with a hybrid model for complex malformation associated with late correction. METHODS: The present report describes a case of frontoethmoidal encephalocele of a 10-year-old girl. Two different methods for planning the approach were developed: 1) a hybrid hands-on model and 2) augmented reality, using a cell phone app and headset display. The customized hybrid model was created based on patient's imaging. The augmented reality app was developed with a real-time interface. RESULTS: The hybrid model recreated anatomic alterations, thereby allowing a multidisciplinary team to determine an appropriate surgical approach. All aspects of the surgical procedure were simulated. A pre- to postoperative comparison was made, which emphasized benefit of tridimensional anatomical relationships using augmented reality tool and its role in preoperative planning. CONCLUSIONS: The authors believe this new multimodality preoperative platform could be a useful method to improve multidisciplinary discussion as well as a powerful tool for teaching and planning.

Human herpesvirus DNA occurrence in intracranial aneurysmal wall: illustrative case.

BACKGROUND: Subarachnoid hemorrhages secondary to intracranial aneurysms (IAs) are events of high mortality. These neurological vascular diseases arise from local and systemic inflammation that culminates in vessel wall changes. They may also have a possible relationship with chronic viral infections, such as human herpesvirus (HHV), and especially Epstein-Barr virus (EBV), which causes several medical conditions. This is the first description of the presence of HHV deoxyribonucleic acid (DNA) in a patient with IA. OBSERVATIONS: A 61-year-old woman with a downgraded level of consciousness underwent radiological examinations that identified a 10-mm ruptured aneurysm in the anterior communicating artery. A microsurgery clip was performed to definitively treat the aneurysm and occurred without surgical complications. Molecular analysis of the material obtained revealed the presence of EBV DNA in the aneurysm wall. The patient died 21 days after admission due to clinical complications and brain swelling. LESSONS: This is the first description of the presence of herpesvirus DNA in a patient with IA, presented in 2.8% of our data. These findings highlight that viral infection may contribute to the pathophysiology and is an additional risk factor for IA formation, progression, and rupture by modulating vessel wall inflammation and structural changes in chronic infections.

Realistic simulator for craniosynostosis endoscopic approach.

Craniosynostosis is a premature fusion of cranial sutures, and it requires surgery to decrease cranial pressure and remodel the affected areas. However, mastering these procedures requires years of supervised training. Several neurosurgical training simulators have been created to shorten the learning curve. Laboratory training is fundamental for acquiring familiarity with the necessary techniques and skills to properly handle instruments. This video presents a novel simulator for training on the endoscopic treatment for scaphocephaly and trigonocephaly, covering all aspects of the procedure, from patient positioning to performing osteotomies. The video can be found here: https://vimeo.com/512526147.

A hybrid simulation model for pre-operative planning of transsphenoidal encephalocele.

Congenital transsphenoidal encephalocele (CTE) surgical correction is a challenging procedure. Although rare, this anomaly, characterized with neural herniation elements, including the pituitary gland or optic pathway through the sphenoid bone with anatomical alteration, can be presented in many different ways and should be individually analyzed. Significant advances in medical technology and the 3D models may simulate the complex anatomical relations of the human body. Nowadays, medical education relies on the availability of standardized materials that can reliably emulate human anatomy. Therefore, realistic anatomical models have become an alternative for cadavers or animal specimens. In this technical note, the authors present a new technique to create personalized models that combine 3D printing, molding, and casting to create an anatomically and tactilely realistic model based on magnetic resonance and computerized tomography images. Produced from different silicon types, the model recreated the anatomic alterations precisely, allowing a multidisciplinary team to determine the adequate surgical approach for this patient. We describe a case of congenital transsphenoidal encephalocele of a 3-year-old boy, whose surgical correction was planned using a hybrid model. The technical description of the model is given in detail. This new hybrid model allowed a detailed discussion of the surgical approach aspects by having tissues of different consistencies and resistances and a very high prediction rate. This approach may allow a reduction in surgery time and possible complications after operative procedures.

Spinal cord tumor leading to urinary retention resulting from Schistosoma mansoni infection in a child.

Schistosomose mansoni is an endemic disease in Brazil. It rarely affects the central nervous system, particularly in children. We report the case of a child that presented with an acute spinal cord compression condition, resulting from a mass that proved to be a granuloma caused by a Schistosoma mansoni infection. Proper treatment had no effect on the regression of urological symptoms and the child had to undergo a Mitrofanoff principle.

Development and Evaluation of Pediatric Mixed-Reality Model for Neuroendoscopic Surgical Training.

OBJECTIVE: Neurosurgical training requires several years of supervised procedures and represents a long and challenging process. The development of surgical simulation platforms is essential to reducing the risk of potentially intraoperative severe errors arising from inexperience. To present and perform a phase I validation process of a mixed reality simulation (realistic and virtual simulators combined) for neuroendoscopic surgical training. METHODS: Tridimensional videos were developed by the 3DS Max program. Physical simulators were made with a synthetic thermoretractile and thermosensible rubber, which, when combined with different polymers, produces >30 different textures that simulate consistencies and mechanical resistance of human tissues. Questionnaires regarding the role of virtual and realistic simulators were applied to experienced neurosurgeons to assess the applicability of the mixed-reality simulation for neuroendoscopic surgical training. RESULTS: The model was considered as a potential tool for training new residents in neuroendoscopic surgery. It was also adequate for practical application with inexperienced surgeons. According to the overall score, 83% of the surgeons believed that the realistic physical simulator presents distortions when compared with the real anatomic structure, afterwards the model improved 66% tridimensional reconstruction and 66% reported that the virtual simulator allowed a multiangular perspective ability. CONCLUSIONS: This model provides a highly effective way of working with 3-dimensional data and significantly enhances the learning of surgical anatomy and operative strategies. The combination of virtual and realistic tools may safely improve and abbreviate the surgical learning curve.

Augmented reality and physical hybrid model simulation for preoperative planning of metopic craniosynostosis surgery.

OBJECTIVE: The main objective of neurosurgery is to establish safe and reliable surgical techniques. Medical technology has advanced during the 21st century, enabling the development of increasingly sophisticated tools for preoperative study that can be used by surgeons before performing surgery on an actual patient. Laser-printed models are a robust tool for improving surgical performance, planning an operative approach, and developing the skills and strategy to deal with uncommon and high-risk intraoperative difficulties. Practice with these models enhances the surgeon's understanding of 3D anatomy but has some limitations with regard to tactile perception. In this study, the authors aimed to develop a preoperative planning method that combines a hybrid model with augmented reality (AR) to enhance preparation for and planning of a specific surgical procedure, correction of metopic craniosynostosis, also known as trigonocephaly. METHODS: With the use of imaging data of an actual case patient who underwent surgical correction of metopic craniosynostosis, a physical hybrid model (for hands-on applications) and an AR app for a mobile device were created. The hybrid customized model was developed by using analysis of diagnostic CT imaging of a case patient with metopic craniosynostosis. Created from many different types of silicone, the physical model simulates anatomical conditions, allowing a multidisciplinary team to deal with different situations and to precisely determine the appropriate surgical approach. A real-time AR interface with the physical model was developed by using an AR app that enhances the anatomic aspects of the patient's skull. This method was used by 38 experienced surgeons (craniofacial plastic surgeons and neurosurgeons), who then responded to a questionnaire that evaluated the realism and utility of the hybrid AR simulation used in this method as a beneficial educational tool for teaching and preoperative planning in performing surgical metopic craniosynostosis correction. RESULTS: The authors developed a practice model for planning the surgical cranial remodeling used in the correction of metopic craniosynostosis. In the hybrid AR model, all aspects of the surgical procedure previously performed on the case patient were simulated: subcutaneous and subperiosteal dissection, skin incision, and skull remodeling with absorbable miniplates. The pre- and postoperative procedures were also carried out, which emphasizes the role of the AR app in the hybrid model. On the basis of the questionnaire, the hybrid AR tool was approved by the senior surgery team and considered adequate for educational purposes. Statistical analysis of the questionnaire responses also highlighted the potential for the use of the hybrid model in future applications. CONCLUSIONS: This new preoperative platform that combines physical and virtual models may represent an important method to improve multidisciplinary discussion in addition to being a powerful teaching tool. The hybrid model associated with the AR app provided an effective training environment, and it enhanced the teaching of surgical anatomy and operative strategies in a challenging neurosurgical procedure.

The Craniosynostosis Puzzle: New Simulation Model for Neurosurgical Training.

BACKGROUND: Neurosurgical training usually requires long hours for hands-on procedures, making it difficult for inexperienced surgeons to quickly learn in an error-proof environment. The objective of this study was to propose a puzzle-like new model for neurosurgical education that simulates craniosynostosis correction (scaphocephaly type) using Renier's H technique. A model of a 3-dimensional (3D) anatomic simulator for craniosynostosis training is presented and evaluated. METHODS: The cranial model was created using 1-mm computed tomography scan images from patients with scaphocephaly in the Digital Imaging and Communications in Medicine format. This information was processed using an algorithm to generate a 3D biomodel in resin. The puzzle model and its variable training models were assessed qualitatively by a team of expert neurosurgeons. Next, the model was applied in trainees and was evaluated using specific questionnaires. RESULTS: Experts and trainees evaluated the model. The mean number of attempts without errors was 2.3 ± 0.675, for 1 error was 2.2 ± 0.918, and for 2 errors was 1.3 ± 0.707. The mean score of the simulator was 9.2 ± 0.421. Twelve residents (second evaluation) answered the questionnaire with a positive assessment of diagnosis capabilities, appropriateness of the model, time commitment, adequate environment, reliable 3D reconstruction, and teaching method. Three participants had used a 3D simulator previously, and the simulator was evaluated obtaining a 9.9 final average (range, 0-10). CONCLUSIONS: The puzzle may be a complementary tool for surgical training. It allows several degrees of immersion and realism, offering symbolic, geometric, and dynamic information with 3D visualization. It provides additional data to support the practice of complex surgical procedures without exposing real patients to undue risk.

Development and evaluation of a new pediatric mixed-reality model for neurosurgical training.

OBJECTIVE: Craniosynostosis is a premature cranial suture junction and requires a craniectomy to decrease cranial compression and remodel the affected areas of the skull. However, mastering these neurosurgical procedures requires many years of supervised training. The use of surgical simulation can reduce the risk of intraoperative error. The authors propose a new instrument for neurosurgical education, which mixes reality with virtual and realistic simulation for repair of craniosynostosis (scaphocephaly type). METHODS: This study tested reality simulators with a synthetic thermo-retractile/thermosensitive rubber joined with different polymers. To validate the model, 18 experienced surgeons participated in this study using 3D videos developed using 3DS Max software. Renier's "H" technique for craniosynostosis correction was applied during the simulation. All participants completed questionnaires to evaluate the simulator. RESULTS: An expert surgical team approved the craniosynostosis reality and virtual simulators. More than 94% of participants found the simulator relevant, considering aspects such as weight, surgical positioning, dissection by planes, and cranial reconstruction. The consistency and material resistance were also approved on average by more than 60% of the surgeons. CONCLUSIONS: The virtual simulator demands a high degree of effectiveness with 3D perception in anatomy and operative strategies in neurosurgical training. Physical and virtual simulation with mixed reality required psychomotor and cognitive abilities otherwise acquired only during practical surgical training with supervision.

The Role of Mixed Reality Simulation for Surgical Training in Spine: Phase 1 Validation.

STUDY DESIGN: This study shows the first phase of validation of a new model for realistic training on spine surgery, conducted from January 2014 to November 2015. OBJECTIVE: To propose and validate a new tool for neurosurgical education, associating virtual and realistic simulation (mixed reality), for spine surgery. SUMMARY OF BACKGROUND DATA: Surgical simulation is a relatively new filed that has a lot to offer to neurosurgical education. Training a new surgeon may take years of hands-on procedures, increasing the risk to patient's safety. The development of surgical simulation platforms is therefore essential to reducing the risk of potentially serious risks and improving outcome. METHODS: Sixteen experienced spinal surgeons evaluated these simulators and answered the questionnaire regarding the simulation as a beneficial education tool. They evaluated the simulators in regard to dissection by planes, identification of pathology (lumbar canal stenosis), instrumentation and simulation of cerebrospinal fluid (CSF) leak, and the relevant aspects of the computerized tomography (CT) imaging. RESULTS: The virtual and physical simulators for spine surgery were approved by an expert surgery team, and considered adequate for educational purposes. The proportion of the answers was estimated by the confidence intervals. CONCLUSION: The surgery team considered that this virtual simulation provides a highly effective training environment, and it significantly enhances teaching of surgical anatomy and operative strategies in the neurosurgical field. A mixture of physical and virtual simulation provided the desired results of enhancing the requisite psychomotor and cognitive skills, previously acquired only during a surgical apprenticeship. The combination of these tools may potentially improve and abbreviate the learning curve for trainees, in a safe environment. LEVEL OF EVIDENCE: 3.

História da simulação cirúrgica e sua aplicação em Neurocirurgia / History of surgical simulation and its application in Neurosurgery

OBJETIVOS: Neste artigo, os autores abordam a evolução histórica da simulação cirúrgica, tendo como foco a sua aplicação em Neurocirurgia. MÉTODOS: A revisão da literatura foi feita nas bases de dados PubMed/Medline e Scopus, utilizando os termos "history AND simulation"; e "simulation AND neurosurgery". Não houve limite de data de publicação. RESULTADOS: Foram selecionados 30 artigos cujo conteúdo inclui dados de interesse para o objetivo do estudo. A simulação tem sido usada durante séculos de várias formas, incluindo dissecação de cadáveres pelos primeiros médicos (como Galeno) e treinamento militar (como por exemplo nos jogos de guerra). Modelos anatômicos foram criados no século XVIII e seguiram se aperfeiçoando nos séculos seguintes. Já a simulação por realidade virtual foi primeiramente utilizada em 1987, popularizando-se no início da década de 1990. Posteriormente foram criados modelos anatômicos sintéticos que reproduzem cenários cirúrgicos próximos ao real, com grande aplicabilidade atualmente. CONCLUSÕES: A revisão da literatura destacou aspectos evolutivos da simulação e sua aplicação atual em educação médica. As inovações nesse campo foram muito apreciadas por membros da comunidade neurocirúrgica, que reconheceram o vasto potencial da simulação para revolucionar esta especialidade, onde erros intraoperatórios podem ter consequências desastrosas. Esta revisão histórica poderá contribuir para melhor compreensão do relevante papel da simulação e também para sua implementação no currículo médico, especialmente em especialidades de alta complexidade, como a Neurocirurgia.

OBJECTIVES: In this article, the authors address the historical evolution of surgical simulation, focusing on its application in Neurosurgery. METHODS: Literature search was done in the PubMed/Medline and Scopus databases, using the terms "history AND simulation"; and "simulation AND neurosurgery". There was no limit for the publication date. RESULTS: We selected 30 articles whose contents included data of interest for the objective of the study. Simulation has been used for centuries in a variety of ways, including the dissection of corpses by the early physicians (such as Galeno) and military training (for example in war games). Anatomical models were created in the eighteenth century and continued to improve in the following centuries. Virtual reality simulation was first used in 1987 and became popular in the early 1990s. Subsequently, synthetic anatomical models were created that reproduce surgical scenarios close to the real one, with great applicability today. CONCLUSIONS: This literature review highlighted evolutionary aspects of simulation and its current application in medical education. Innovations in this field were highly appreciated by members of the neurosurgical community who recognized the vast potential of simulation to revolutionize this specialty, where intraoperative errors can have disastrous consequences. This historical review may contribute to a better understanding of the relevant role of simulation and for its implementation in the medical curriculum, especially in high complexity specialties such as Neurosurgery.