Identification of The Unique Subtype of Macrophages in Aneurysm Lesions at the Growth Phase.

OBJECTIVES: Recent experimental studies have defined intracranial aneurysms as a macrophage-mediated chronic inflammatory disease affecting intracranial arteries. Although there are various subtypes in macrophages, what type of macrophages is present in lesions during the disease development remains to be elucidated. METHODS: The previously-established aneurysm model of rats was used. Macrophages were labeled with the fluorescent protein and isolated by a laser-microdissection method. The comprehensive gene expression profile analyses and gene ontology analyses was then done to identify a macrophage subtype present in lesions at the growth phase. RESULTS: The gene expression profile data of total 52 macrophages infiltrating into the lesions was acquired. The principal component analysis revealed the monotonous macrophage subtype. By comparing the profile identified with one from in vitro-differentiated M0 or M1 macrophages, the macrophages in the lesions were belonged to the simple and unique subtype. Because the perception of signaling from nervous system was highlighted as up-represented terms through gene ontology analyses, the macrophage subtype in lesions at the growth phase might be differentiated under the influence of nervous system in the microenvironment. The histopathological examinations supported the above notion by confirming the presence of nerves in the adventitia. CONCLUSIONS: The findings from the present study have provided the useful insights about the macrophage subtype in aneurysm lesions at the growth phase and also proposed its ability as a therapeutic target.

Computational fluid dynamic analysis of the initiation of cerebral aneurysms.

OBJECTIVE: Relationships between aneurysm initiation and hemodynamic factors remain unclear since de novo aneurysms are rarely observed. Most previous computational fluid dynamics (CFD) studies have used artificially reproduced vessel geometries before aneurysm initiation for analysis. In this study, the authors investigated the hemodynamic factors related to aneurysm initiation by using angiographic images in patients with cerebral aneurysms taken before and after an aneurysm formation. METHODS: The authors identified 10 cases of de novo aneurysms in patients who underwent follow-up examinations for existing cerebral aneurysms located at a different vessel. The authors then reconstructed the vessel geometry from the images that were taken before aneurysm initiation. In addition, 34 arterial locations without aneurysms were selected as control cases. Hemodynamic parameters acting on the arterial walls were calculated by CFD analysis. RESULTS: In all de novo cases, the aneurysmal initiation area corresponded to the highest wall shear stress divergence (WSSD point), which indicated that there was a strong tensile force on the arterial wall at the initiation area. The other previously reported parameters did not show such correlations. Additionally, the pressure loss coefficient (PLc) was statistically significantly higher in the de novo cases (p < 0.01). The blood flow impact on the bifurcation apex, or the secondary flow accompanied by vortices, resulted in high tensile forces and high total pressure loss acting on the vessel wall. CONCLUSIONS: Aneurysm initiation may be more likely in an area where both tensile forces acting on the vessel wall and total pressure loss are large.

[History and Recent Development of Basic Research Using an Experimental Intracranial Aneurysm Model].

Since intracranial aneurysm(IA)is a disease that follows an extremely unpredictable course, from initiation to rupture, experimental models have greatly contributed to a better understanding of IA pathophysiology. This article aims to review the history of IA models through the pivotal theme of the ideal IA model. In addition, this article introduces updated findings from the application of these experimental models. Though the first IA model, known as a venous pouch model, was reported in 1954, it mimicked only the shape of the IA, without reproducing its pathological structure or blood-flow characteristics. Currently, two models are generally applied: the "Hashimoto model," produced by unilateral common carotid artery(CCA)ligation followed by systemic hypertension and weakening of the vascular wall, and the "elastase injection model," induced by intraventricular elastase injection and also followed by systemic hypertension. In addition, other models, including a rabbit basilar top IA, developed after bilateral CCA ligation, and an artificial bifurcation model, generated by an anastomosis between the CCAs, have been found to be valuable for computational fluid dynamics analysis. Through this advancement, the IA model has gradually elucidated the pathophysiology of IA as a flow-induced inflammatory disease. Nowadays, vascular inflammation is suggested to be regulated by bacterial flora. Further development of IA models and a better understanding of IA pathophysiology are expected in the future.

Hemodynamic Force as a Potential Regulator of Inflammation-Mediated Focal Growth of Saccular Aneurysms in a Rat Model.

Past studies have elucidated the crucial role of macrophage-mediated inflammation in the growth of intracranial aneurysms (IAs), but the contributions of hemodynamics are unclear. Considering the size of the arteries, we induced de novo aneurysms at the bifurcations created by end-to-side anastomoses with the bilateral common carotid arteries in rats. Sequential morphological data of induced aneurysms were acquired by magnetic resonance angiography. Computational fluid dynamics analyses and macrophage imaging by ferumoxytol were performed. Using this model, we found that de novo saccular aneurysms with a median size of 3.2 mm were induced in 20/45 (44%) of animals. These aneurysms mimicked human IAs both in morphology and pathology. We detected the focal growth of induced aneurysms between the 10th and 17th day after the anastomosis. The regional maps of hemodynamic parameters demonstrated the area exposed to low wall shear stress (WSS) and high oscillatory shear index (OSI) colocalized with the regions of growth. WSS values were significantly lower in the growing regions than in ones without growth. Macrophage imaging showed colocalization of macrophage infiltration with the growing regions. This experimental model demonstrates the potential contribution of low WSS and high OSI to the macrophage-mediated growth of saccular aneurysms.

Involvement of neutrophils in machineries underlying the rupture of intracranial aneurysms in rats.

Subarachnoid hemorrhage due to rupture of an intracranial aneurysm has a quite poor prognosis after the onset of symptoms, despite the modern technical advances. Thus, the mechanisms underlying the rupture of lesions should be clarified. To this end, we obtained gene expression profile data and identified the neutrophil-related enriched terms in rupture-prone lesions using Gene Ontology analysis. Next, to validate the role of neutrophils in the rupture of lesions, granulocyte-colony stimulating factor (G-CSF) was administered to a rat model, in which more than half of induced lesions spontaneously ruptured, leading to subarachnoid hemorrhage. As a result, G-CSF treatment not only increased the number of infiltrating neutrophils, but also significantly facilitated the rupture of lesions. To clarify the mechanisms of how neutrophils facilitate this rupture, we used HL-60 cell line and found an enhanced collagenolytic activity, corresponding to matrix metalloproteinase 9 (MMP9), upon inflammatory stimuli. The immunohistochemical analyses revealed the accumulation of neutrophils around the site of rupture and the production of MMP9 from these cells in situ. Consistently, the collagenolytic activity of MMP9 could be detected in the lysate of ruptured lesions. These results suggest the crucial role of neutrophils to the rupture of intracranial aneurysms; implying neutrophils as a therapeutic or diagnostic target candidate.

Dedifferentiation of smooth muscle cells in intracranial aneurysms and its potential contribution to the pathogenesis.

Smooth muscle cells (SMCs) are the major type of cells constituting arterial walls and play a role to maintain stiffness via producing extracellular matrix. Here, the loss and degenerative changes of SMCs become the major histopathological features of an intracranial aneurysm (IA), a major cause of subarachnoid hemorrhage. Considering the important role of SMCs and the loss of this type of cells in IA lesions, we in the present study subjected rats to IA models and examined how SMCs behave during disease progression. We found that, at the neck portion of IAs, SMCs accumulated underneath the internal elastic lamina according to disease progression and formed the intimal hyperplasia. As these SMCs were positive for a dedifferentiation marker, myosin heavy chain 10, and contained abundant mitochondria and rough endoplasmic reticulum, SMCs at the intimal hyperplasia were dedifferentiated and activated. Furthermore, dedifferentiated SMCs expressed some pro-inflammatory factors, suggesting the role in the formation of inflammatory microenvironment to promote the disease. Intriguingly, some SMCs at the intimal hyperplasia were positive for CD68 and contained lipid depositions, indicating similarity with atherosclerosis. We next examined a potential factor mediating dedifferentiation and recruitment of SMCs. Platelet derived growth factor (PDGF)-BB was expressed in endothelial cells at the neck portion of lesions where high wall shear stress (WSS) was loaded. PDGF-BB facilitated migration of SMCs across matrigel-coated pores in a transwell system, promoted dedifferentiation of SMCs and induced expression of pro-inflammatory genes in these cells in vitro. Because, in a stenosis model of rats, PDGF-BB expression was expressed in endothelial cells loaded in high WSS regions, and SMCs present nearby were dedifferentiated, hence a correlation existed between high WSS, PDGFB and dedifferentiation in vivo. In conclusion, dedifferentiated SMCs presumably by PDGF-BB produced from high WSS-loaded endothelial cells accumulate in the intimal hyperplasia to form inflammatory microenvironment leading to the progression of the disease.

Eicosapentaenoic acid prevents the progression of intracranial aneurysms in rats.

BACKGROUND: As subarachnoid hemorrhage due to rupture of an intracranial aneurysm (IA) has quite a poor outcome despite of an intensive medical care, development of a novel treatment targeting unruptured IAs based on the correct understanding of pathogenesis is mandatory for social health. METHODS: Using previously obtained gene expression profile data from surgically resected unruptured human IA lesions, we selected G-protein coupled receptor 120 (GPR120) as a gene whose expression is significantly higher in lesions than that in control arterial walls. To corroborate a contribution of GPR120 signaling to the pathophysiology, we used an animal model of IAs and examine the effect of a GPR120 agonist on the progression of the disease. IA lesion was induced in rats through an increase of hemodynamic stress achieved by a one-sided carotid ligation and induced hypervolemia. Eicosapentaenoic acid (EPA) was used as an agonist for GPR120 in this study and its effect on the size of IAs, the thinning of media, and infiltration of macrophages in lesions were examined. RESULT: EPA administered significantly suppressed the size of IAs and the degenerative changes in the media in rats. EPA treatment also inhibited infiltration of macrophages, a hallmark of inflammatory responses in lesions. In in vitro experiments using RAW264.7 cells, pre-treatment of EPA partially suppressed lipopolysaccharide-induced activation of nuclear factor-kappa B and also the transcriptional induction of monocyte chemoattractant protein 1 (MCP-1), a major chemoattractant for macrophages to accumulate in lesions. As a selective agonist of GPR120, TUG-891, could reproduce the effect of EPA in RAW264.7 cells, EPA presumably acted on this receptor to suppress inflammatory responses. Consistently, EPA remarkably suppressed MCP-1 expression in lesions, suggesting the in vivo relevance of in vitro studies. CONCLUSIONS: These results combined together suggest the potential of the medical therapy targeting GPR120 or using EPA to prevent the progression of IAs.

Two Diverse Hemodynamic Forces, a Mechanical Stretch and a High Wall Shear Stress, Determine Intracranial Aneurysm Formation.

Intracranial aneurysm (IA) usually induced at a bifurcation site of intracranial arteries causes a lethal subarachnoid hemorrhage. Currently, IA is considered as a macrophage-mediated inflammatory disease triggered by a high wall shear stress (WSS) on endothelial cells. However, considered the fact that a high WSS can be observed at every bifurcation site, some other factors are required to develop IAs. We therefore aimed to clarify mechanisms underlying the initiation of IAs using a rat model. We found the transient outward bulging and excessive mechanical stretch at a prospective site of IA formation. Fibroblasts at the adventitia of IA walls were activated and produced (C-C motif) ligand 2 (CCL2) as well in endothelial cells loaded on high WSS at the earliest stage. Consistently, the mechanical stretch induced production of CCL2 in primary culture of fibroblasts and promoted migration of macrophages in a Transwell system. Our results suggest that distinct hemodynamic forces, mechanical stretch on fibroblasts and high WSS on endothelial cells, regulate macrophage-mediated IA formation.

Rat Model of Intracranial Aneurysm: Variations, Usefulness, and Limitations of the Hashimoto Model.

Given the poor outcome of subarachnoid hemorrhage due to rupture of intracranial aneurysms (IAs) and high prevalence of IAs in general public, elucidation of mechanisms underlying the pathogenesis of the disease and development of effective treatment are mandatory for social health. Recent experimental findings have revealed the crucial contribution of macrophage-mediated chronic inflammation to and greatly promoted our understanding of the pathogenesis. Also a series of studies have proposed the potential of anti-inflammatory drugs as therapeutic ones. In this process, a rodent model of IAs plays an indispensable role. Basic concept of IA induction in such kind of models is that IA formation is triggered by hemodynamic stress loaded on damaged arterial walls. To be more precise, although detailed procedures are different among researchers, animals are subjected to a ligation of a unilateral carotid artery and systemic hypertension achieved by a salt overloading, and IAs are induced at the contralateral bifurcation site. Importantly, trigger of IA formation in the model mimics human one, and IA lesions induced share similarity in histology with human ones such as degenerative changes of media. For further elucidating the pathogenesis, we need to well understand variations, usefulness, and also limits of this model.

Vasa vasorum formation is associated with rupture of intracranial aneurysms.

OBJECTIVE: Subarachnoid hemorrhage (SAH) has a poor outcome despite modern advancements in medical care. The development of a novel therapeutic strategy to prevent rupture of intracranial aneurysms (IAs) or a novel diagnostic marker to predict rupture-prone lesions is thus mandatory. Therefore, in the present study, the authors established a rat model in which IAs spontaneously rupture and examined this model to clarify histopathological features associated with rupture of lesions. METHODS: Female Sprague Dawley rats were subjected to bilateral ovariectomy; the ligation of the left common carotid, the right external carotid, and the right pterygopalatine arteries; induced systemic hypertension; and the administration of a lysyl oxidase inhibitor. RESULTS: Aneurysmal SAH occurred in one-third of manipulated animals and the locations of ruptured IAs were exclusively at a posterior or anterior communicating artery (PCoA/ACoA). Histopathological examination using ruptured IAs, rupture-prone IAs induced at a PCoA or ACoA, and IAs induced at an anterior cerebral artery-olfactory artery bifurcation that never ruptured revealed the formation of vasa vasorum as an event associated with rupture of IAs. CONCLUSIONS: The authors propose the contribution of a structural change in an adventitia, i.e., vasa vasorum formation, to the rupture of IAs. Findings from this study provide important insights about the pathogenesis of IAs.

RNA sequencing analysis revealed the induction of CCL3 expression in human intracranial aneurysms.

Intracranial aneurysm (IA) is a socially important disease as a major cause of subarachnoid hemorrhage. Recent experimental studies mainly using animal models have revealed a crucial role of macrophage-mediated chronic inflammatory responses in its pathogenesis. However, as findings from comprehensive analysis of unruptured human IAs are limited, factors regulating progression and rupture of IAs in humans remain unclear. Using surgically dissected human unruptured IA lesions and control arterial walls, gene expression profiles were obtained by RNA sequence analysis. RNA sequencing analysis was done with read count about 60~100 million which yielded 6~10 billion bases per sample. 79 over-expressed and 329 under-expressed genes in IA lesions were identified. Through Gene Ontology analysis, 'chemokine activity', 'defense response' and 'extracellular region' were picked up as over-represented terms which included CCL3 and CCL4 in common. Among these genes, quantitative RT-PCR analysis using another set of samples reproduced the above result. Finally, increase of CCL3 protein compared with that in control arterial walls was clarified in IA lesions. Findings of the present study again highlight importance of macrophage recruitment via CCL3 in the pathogenesis of IA progression.

Real-time Imaging of an Experimental Intracranial Aneurysm in Rats.

Subarachnoid hemorrhage due to rupture of a pre-existing intracranial aneurysm has quite a poor outcome in spite of intensive medical care. Hemodynamic stress loaded on intracranial arterial walls is considered as a trigger and a regulator of formation and progression of the disease, but how intracranial arterial walls or intracranial aneurysm walls behave under hemodynamic stress loading remains unclear. The purpose of this study was to visualize and analyze the wall motion of intracranial aneurysms to detect a pathological flow condition. We subjected a transgenic rat line, in which endothelial cells are specifically visualized by expression of a green fluorescent protein, to an intracranial aneurysm model and observed a real-time motion of intracranial arterial walls or intracranial aneurysm walls by a multiphoton laser confocal microscopy. The anterior cerebral artery-olfactory artery bifurcation was surgically exposed for the monitoring. First, we observed the proper flow-dependent physiological dilatation of a contralateral intracranial artery in response to increase of blood flow by one side of carotid ligation. Next, we observed intracranial aneurysm lesions induced in a rat model and confirmed that a wall motion of the dome was static, whereas that of the neck was more dynamic in response to pulsation of blood flow. We successfully monitored a real-time motion of intracranial aneurysm walls. Findings obtained from such a real-time imaging will provide us many insights especially about the correlation of mechanical force and the pathogenesis of the disease and greatly promote our understanding of the disease.

Intraoperative and Postoperative Bleeding in Microvascular Decompression for Trigeminal Neuralgia.

OBJECTIVE: The surgical approach for the trigeminal nerve involves veins connected to the superior petrosal and tentorial sinus, and we should pay special attention to these veins. We investigated intraoperative and postoperative bleeding using our database. METHODS: A prospectively accumulated database of 247 microvascular decompression surgeries for trigeminal neuralgia over the past 10 years was analyzed. Intraoperative and postoperative bleeding was confirmed with surgical records, videos, and computed tomography. Of 235 patients, 161 were female; 85 patients were >70 years old at the time of surgery; 96 surgeries involved the left side. RESULTS: Intraoperative venous bleeding was encountered in 29 surgeries (12%): from the superior petrosal vein/sinus in 18 and the hemispheric bridging vein/tentorial sinus in 11. Massive bleeding occurred from the superior petrosal sinus owing to tear of the entrance of the superior petrosal vein in 4 surgeries and from the tentorial sinus in 3; bleeding was controlled by Surgicel with fibrin glue. Postoperative bleeding occurred in 11 surgeries (4%): intracerebellar hematoma in 2, subarachnoid hemorrhage in 3, subdural hemorrhage in 3, supratentorial subdural hemorrhage in 2, and supratentorial epidural hematoma in 1. These lesions were associated with intraoperative bleeding in 1 case, a trans-horizontal fissure approach in 1 case, coagulation of the petrosal vein in 2 cases, and unknown reasons in 7 cases. Cure without medication was achieved in 218 surgeries at an average follow-up of 4.2 years. CONCLUSIONS: Microvascular decompression for trigeminal neuralgia involves potential risks of intraoperative and postoperative bleeding.

Macrophage Imaging of Cerebral Aneurysms with Ferumoxytol: an Exploratory Study in an Animal Model and in Patients.

OBJECTIVE: The purpose of this study is to assess the validity and feasibility of macrophage imaging using an ultrasmall superparamagnetic iron oxide nanoparticle, ferumoxytol, in the cerebral aneurysmal wall in an animal model and in humans. MATERIALS AND METHODS: Engulfment of ferumoxytol by primary culture of macrophages and RAW264.7 cells was assessed. Uptake of ferumoxytol was evaluated histologically in a cerebral aneurysmal model in rats. In an exploratory clinical study of magnetic resonance macrophage imaging, 17 unruptured aneurysms in 17 patients were imaged using thin-slice gapless magnetic resonance images of 2D-gradient-recalled echo (2D-GRE) and 3D-T1-fast-spin echo sequences on day 0 and of the same sequences with infusion of ferumoxytol 24 hours after the first imaging. Pre- and postinfusion images were evaluated independently by 2 medical doctors. RESULTS: Engulfment of ferumoxytol was confirmed in vitro, but the amount of ferumoxytol uptake was independent of the activation state or the differentiation state. Ferumoxytol uptake in CD68-positive cells was observed in the cerebral arterial walls of 4 out of 15 (26.7%) experimentally induced aneurysms in rats. In a clinical study, 17 aneurysms were enrolled and 2 aneurysms were not assessed because of incomplete images. Eleven aneurysms without oral intake of recent anti-inflammatory agents of the remaining 15 aneurysms showed ferumoxytol uptake on 2D-GRE subtraction images, and the size of the aneurysms was significantly related to positive images. CONCLUSIONS: Ferumoxytol uptake was confirmed in cultured macrophages and in the cerebral aneurysmal wall in rats. Thin-slice gapless magnetic resonance imaging with ferumoxytol in human cerebral aneurysmal walls may reflect macrophages in the cerebral aneurysmal wall, but its application to small-sized lesions may be restricted.

Nonspastic hemifacial spasm confirmed by abnormal muscle responses.

BACKGROUND: Hemifacial spasm is usually diagnosed by inspection which mainly identifies involuntary movements of orbicularis oculi. Assessing abnormal muscle responses (AMR) is another diagnostic method. CASE DESCRIPTION: We report a case of left hemifacial spasm without detectable involuntary facial movements. The patient was a 48-year-old man with a long history of subjective left facial twitching. On magnetic resonance imaging (MRI), the left VIIth cranial nerve was compressed by the left anterior inferior cerebellar artery (AICA), which was in turn compressed by the left vertebral artery. We initially treated him with botulinum toxin. We were able to record AMR, and hemifacial spasm occurred after AMR stimulation, although no spasm was detectable by inspection. Subsequently, we performed microvascular decompression with transposition of the AICA that compressed the VIIth cranial nerve. His hemifacial spasm resolved by 5 weeks after surgery and was not induced by AMR stimulation. CONCLUSION: Hemifacial spasm can sometimes be diagnosed by detecting AMR rather than by visual inspection. We propose that such hemifacial spasm should be termed nonspastic hemifacial spasm.

T cell function is dispensable for intracranial aneurysm formation and progression.

Given the social importance of intracranial aneurysm as a major cause of a lethal subarachnoid hemorrhage, clarification of mechanisms underlying the pathogenesis of this disease is essential for improving poor prognosis once after rupture. Previous histopathological analyses of human aneurysm walls have revealed the presence of T cells in lesions suggesting involvement of this type of cell in the pathogenesis. However, it remains unclear whether T cell actively participates in intracranial aneurysm progression. To examine whether T cell is involved in aneurysm progression, intracranial aneurysm model of rat was used. In this model, aneurysm is induced by increase in hemodynamic force loaded on bifurcation site of intracranial arteries where aneurysms are developed. Deficiency in T cells and pharmacological inhibition of T cell function were applied to this model. CD3-positive T cells were present in human aneurysm walls, whose number was significantly larger compared with that in control arterial walls. Deficiency in T cells in rats and pharmacological inhibition of T cell function by oral administration of Cyclosporine A both failed to affect intracranial aneurysm progression, degenerative changes of arterial walls and macrophage infiltration in lesions. Although T cells are detectable in intracranial aneurysm walls, their function is dispensable for macrophage-mediated inflammation and degenerative changes in arterial walls, which presumably leads to intracranial aneurysm progression.

A sphingosine-1-phosphate receptor type 1 agonist, ASP4058, suppresses intracranial aneurysm through promoting endothelial integrity and blocking macrophage transmigration.

BACKGROUND AND PURPOSE: Intracranial aneurysm (IA), common in the general public, causes lethal subarachnoid haemorrhage on rupture. It is, therefore, of utmost importance to prevent the IA from rupturing. However, there is currently no medical treatment. Recent studies suggest that IA is the result of chronic inflammation in the arterial wall caused by endothelial dysfunction and infiltrating macrophages. The sphingosine-1-phosphate receptor type 1 (S1P1 receptor) is present on the endothelium and promotes its barrier function. Here we have tested the potential of an S1P1 agonist, ASP4058, to prevent IA in an animal model. EXPERIMENTAL APPROACH: The effects of a selective S1P1 agonist, ASP4058, on endothelial permeability and migration of macrophages across an endothelial cell monolayer were tested in vitro using a Transwell system, and its effects on the size of IAs were evaluated in a rat model of IA. KEY RESULTS: S1P1 receptor was expressed in endothelial cells of human IA lesions and control arterial walls. ASP4058 significantly reduced FITC-dextran leakage through an endothelial monolayer and suppressed the migration of macrophages across the monolayer in vitro. Oral administration of ASP4058 reduced the vascular permeability, macrophage infiltration and size of the IAs by acting as an S1P1 agonist in the rat model. This effect was mimicked by another two structurally-unrelated S1P1 agonists. CONCLUSION AND IMPLICATIONS: A selective S1P1 agonist is a strong drug candidate for IA treatment as it promotes the endothelial cell barrier and suppresses the trans-endothelial migration of macrophages in IA lesions.

[Emergency Decompressive Craniotomy in the Emergency Room was Effective in Severe Acute Subdural Hematoma Treatment:Two Case Reports].

The outcome of severe acute subdural hematoma is unfavorable. In particular, patients with levels of consciousness of Glasgow Coma Scale(GCS)3 or 4 tend to be refractory to treatment. Decompressive craniotomy should be promptly performed to remove hematoma. However, if an operating room is not immediately available, emergency burr hole surgery is sometimes performed in the emergency room(primary care room)prior to craniotomy. A previous study has reported that the interval from injury to surgery influences the outcome of severe acute subdural hematoma. Therefore, emergency decompression is important to effectively treat patients with severe acute subdural hematoma. We present the cases of two patients with acute subdural hematomas. In both cases, emergency decompressive craniotomy(hematoma removal after craniotomy and external decompression)was performed in the emergency room of the Emergency and Critical Care Center. In both cases, the surgery was followed by favorable outcomes. Case 1 was a 36-year-old female. The patient's level of consciousness upon arrival was GCS 3. The interval from injury to diagnosis on the basis of CT findings was 75 minutes. Surgery began 20 minutes after diagnosis. Case 2 was a 25-year-old male. The second patient's level of consciousness upon arrival was GCS 4. The interval from injury to diagnosis on the basis of CT findings was 60 minutes. Surgery was begun 40 minutes after diagnosis. In both patients, we observed anisocoria and the loss of the light reflex. However, the postoperative course was favorable, and both patients were discharged. In summary, to treat severe acute subdural hematomas, early emergency decompressive craniotomy is optimal. Emergency decompressive surgery in the emergency room is independent of operating room or staff. Therefore, emergency decompressive craniotomy may improve the outcome of patients with severe acute subdural hematomas.

Clinical Predictors of Intracranial Injuries in Infants with Minor Head Trauma.

OBJECTIVE: Minor head trauma is common in children. Although most cases are nonsignificant, minor head trauma can lead to preventable intracranial injuries. The aim of this study was to identify clinical predictors of intracranial injuries in infants with minor head trauma. METHODS: Between 2006 and 2013, we retrospectively enrolled infants <11 months old with minor head trauma. Data recorded included age, sex, cause of trauma, fall height, vomiting, bad temper, size and location of scalp hematoma, fracture, and intracranial injuries on computed tomography. RESULTS: Of 549 enrolled infants, 15 (3%) sustained traumatic intracranial injuries: epidural hematoma in 7, subarachnoid hemorrhage in 4, subdural hematoma in 3, and cerebral contusion in 1. Intracranial injuries were found in 8 of 98 infants who had fallen from a >60 cm height, 1 in 197 with fall height >30 cm, and none in 44 with fall height ≤30 cm (P = 0.0001); 1 of 2 with scalp hematomas >6 cm, 10 of 35 with hematomas >3 cm, and 2 of 121 with hematomas ≤3 cm (P = 0.0001); and 9 of 28 with temporal hematoma, 2 of 15 with parietal hematoma, 2 of 22 with occipital hematoma, and none of 98 with frontal hematoma (P = 0.0001). Logistic regression analysis showed that scalp hematoma was related to intracranial injuries (hazard ratio = 21.127, P = 0.0001), whereas age, sex, fall, vomiting, and bad temper were not. CONCLUSIONS: Fall height and size and location of scalp hematoma were associated with intracranial injuries. These factors should be considered when making decisions on radiologic examinations of infants with minor head trauma.