ICH, PHE and IVH volumes were determined by two independent raters (S.U. and D.W.G.) using Analyze 11.0 (AnalyzeDirect, Overland Park, KS, USA) (Figures I–VII Online Supplement ). The raters were blinded to clinical data and to each other’s measurements. Measurements were performed by outlining the hemorrhage and rim of PHE on axial slices in the software’s Region of Interest (ROI) module with a semi-automated edge detection tool. This tool calculates boundaries for each lesion based on Hounsfield Units in the area selected by the rater, the most optimal of which is selected by the rater. Next, boundaries were adjusted after inspection of the three orthogonal planes in the software’s Volume Edit module, which allows for better assessment of the location and distribution of each lesion beyond the two-dimensional axial plane. The three-dimensional view is especially helpful to visualize the extent of PHE throughout the brain in large hemorrhages. To delineate PHE the additional principles that it should be (a) more hypodense than the corresponding region in the contralateral hemisphere and (b) most hypodense immediately surrounding the hemorrhage were employed. The rationale for the latter is that following ICH, transendothelial water flux from the intravascular to the interstitial compartments, both before and after frank blood-brain barrier disruption, occurs initially immediately adjacent to the hematoma.13 (link) Therefore, if a less hypodense area adjacent to the hematoma is followed by a more hypodense area further outward, the latter could represent another entity like an old infarct. Measurements were repeated by one rater (S.U.) after a four-month interval to determine intrarater reliability. All measurements were reviewed by two stroke neurologists (L.A.B. and K.N.S.). Figures 1 depicts a representative example of a subject’s ICH and PHE measurements. PHE volumes were determined on MRI (fluid-attenuated inversion recovery sequence, FLAIR) using the semi-automated edge detection tool to delineate the peri-hematomal hyperintensity.
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Hemorrhage, Brain
Hemorrhage, Brain
Brain hemorrhage, also known as intracerebral hemorrhage, is a type of stroke caused by bleeding within the brain tissue.
It can result from various underlying conditions, such as high blood pressure, trauma, or ruptured blood vessels.
Symptoms may include sudden severe headache, altered level of consciousness, nausea, vomiting, and paralysis.
Prompt medical intervention is crucial to minimize brain damage and improve outcomes.
Accurate diagnosis and treatment planning often require a careful review of relevant research protocols, including those from literature, preprints, and patents.
PubCompare.ai, an AI-driven platform, can help researchers easily locate and compare the best protocols to advance their brain hemorrhage studies, even with a hurman-like typo in the process.
It can result from various underlying conditions, such as high blood pressure, trauma, or ruptured blood vessels.
Symptoms may include sudden severe headache, altered level of consciousness, nausea, vomiting, and paralysis.
Prompt medical intervention is crucial to minimize brain damage and improve outcomes.
Accurate diagnosis and treatment planning often require a careful review of relevant research protocols, including those from literature, preprints, and patents.
PubCompare.ai, an AI-driven platform, can help researchers easily locate and compare the best protocols to advance their brain hemorrhage studies, even with a hurman-like typo in the process.
Most cited protocols related to «Hemorrhage, Brain»
Blood-Brain Barrier
Cerebrovascular Accident
Dietary Supplements
Hematoma
Hemorrhage
Hemorrhage, Brain
Infarction
Inversion, Chromosome
Neurologists
Arteries
Autopsy
BLOOD
Brain
Cardiac Death
Cardiovascular System
Cerebrovascular Accident
Deep Vein Thrombosis
Determination, Blood Pressure
Electrocardiography
Enzymes
Ethics Committees, Research
Heart
Hemorrhage, Brain
Malignant Neoplasms
Minority Groups
Myocardial Infarction
Peripheral Vascular Diseases
Pharmaceutical Preparations
Physicians
Pulmonary Embolism
Stroke, Ischemic
Troponin
Woman
Arterial Occlusion
Cerebral Infarction
Endovascular Procedures
Fibrinolytic Agents
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Hemorrhage, Brain
Infarction
Intracranial Hemorrhage
Neoplasm Metastasis
Perfusion
Reperfusion
Safety
Neurocognitive disorders are progressing particularly in the elderly. It was our objective to investigate early signs of neurodegeneration and of small vessel disease and their neurocognitive correlates. In addition we were interested whether obesity is mirrored in brain structures and functions. To obtain a structural and functional MRI assessment of the brain the following magnetic resonance pulse sequences were applied: i) Magnetization prepared rapid gradient echo using a 3D T1-weighted pulse sequence in order to assess brain structure and to highlight differences between grey and white matter. Based on these data, voxel-based morphometry and cortical thickness measurements were performed. ii) Diffusion weighted imaging at 60 different angles using pulse sequences, which are sensitive to water diffusion and its direction. Based on this information, parameters characterizing white matter such as various characteristics of the diffusion tensor (axial, radial diffusivity, fractional anisotropy etc.) were determined. iii) Resting state functional MRI. Here, oxygenation changes were investigated during rest as a measure for functional connectivity. iv) Fluid-attenuated inversion recovery, which is highly sensitive for the identification of white matter lesions. v) Susceptibility weighted imaging using a T2*-weighted pulse sequence, which is highly sensitive to brain hemorrhage. vi) MR-angiography, which was used for the assessment of arterial brain vessels, e.g. to identify aneurysms.
Structural and functional MRI parameters were used to identify specific neurodegenerative diseases and its pre-stages, subjective and mild cognitive impairment. For Alzheimer’s disease we focussed on atrophy in hippocampal regions and connectivity changes in temporoparietal brain networks, for subtypes of frontotemporal lobar degeneration on changes in structure and function of respective brain regions, for vascular diseases such as small vessel diseases on automatic detection of white matter lesions and changes in connectivity measures [22 (link)–25 (link)].
Structural and functional MRI parameters were used to identify specific neurodegenerative diseases and its pre-stages, subjective and mild cognitive impairment. For Alzheimer’s disease we focussed on atrophy in hippocampal regions and connectivity changes in temporoparietal brain networks, for subtypes of frontotemporal lobar degeneration on changes in structure and function of respective brain regions, for vascular diseases such as small vessel diseases on automatic detection of white matter lesions and changes in connectivity measures [22 (link)–25 (link)].
Aged
Aneurysm
Angiography
Anisotropy
Arteries
Atrophy
Brain
Cell Respiration
Cognitive Impairments, Mild
Cortex, Cerebral
Diffusion
ECHO protocol
fMRI
Frontotemporal Lobar Degeneration
Hemorrhage, Brain
Inversion, Chromosome
Nerve Degeneration
Neurocognitive Disorders
Neurodegenerative Disorders
Nuclear Magnetic Resonance
Obesity
Operator Regions, Genetic
Pulse Rate
Susceptibility, Disease
Vascular Diseases
White Matter
Protocol full text hidden due to copyright restrictions
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Brain
Brain Death
Brain Injuries
Cerebrovascular Accident
Hemorrhage
Hemorrhage, Brain
Infarction
Intracranial Hemorrhage
Patients
Most recents protocols related to «Hemorrhage, Brain»
This was a longitudinal study of a prospective cohort of CKD patients in Korea, called KNOW-CKD (KoreaN cohort study for Outcome in patients With Chronic Kidney Disease). KNOW-CKD is a multicenter prospective cohort study that enrolled adult predialysis patients with CKD stages G1 to G511 (link). Patients were classified into four groups according to the specific cause of CKD at enrollment: glomerulonephritis (GN), diabetic nephropathy (DN), hypertensive nephropathy (HTN), and Polycystic kidney disease (PKD). Each group classification was determined based on pathologic diagnosis if a biopsy result was available (27.6% of total patients: 66.5% of GN group, 6.4% of DN group, 7.3% of HTN group and 1.4% of PKD group). Otherwise, group classifications were based on clinical diagnoses. The biopsy-proven GN consisted as following – 40% IgA nephropathy, 7% focal segment glomerular sclerosis, 6% membranous nephropathy, 5% crescentic GN, 2.4% minimal change disease, and 1.5% lupus nephritis. Non-biopsy-proven GN was defined as the clinical history manifesting chronic GN and the presence of albuminuria or glomerular hematuria with or without an underlying systemic disease causing GN. The active GN population taking immunosuppressant at enrollment was excluded to minimize the heterogeneity by treatment. Diagnosis of DN was strictly based on albuminuria in a patient with type 2 diabetes and the presence of diabetic retinopathy. To exclude DN patients who may have combined GN, diabetic patients with glomerular hematuria were not included in the DN group. HTN was diagnosed by a history of hypertension and the absence of a systemic illness associated with kidney damage. Only the patients with proteinuria < 1.5 g/day and a proportion of urine albumin < 50% of urine protein were included in HTN to exclude the GN population. To diagnose PKD, unified ultrasound criteria were used12 (link). Other causative diseases was categorized as ‘unclassified’ and excluded from our analysis.
A total of 2238 patients enrolled in the study from April 2011 to February 2016. After excluding patients with unclassified etiology or without follow-up data, 2070 patients were finally analyzed in this study for survival analysis with follow up until March 31, 2020. To determine the annual eGFR change and trajectory, we included only those patients (n = 1952) with more than two creatinine measurements (Fig.1 ). Written informed consent from each patient was collected voluntarily at the time of enrollment. The study was approved by the institutional review board of each participating hospital: Chonnam National University Hospital (CNUH-2011-092), Eulji General Hospital (201105-01), Gil Hospital (GIRBA2553), Kangbuk Samsung Medical Center (2011-01-076), Pusan Paik Hospital (11-091), Seoul National University Bundang Hospital (B-1106/129-008), Seoul National University Hospital (H-1704-025-842), Seoul St. Mary’s Hospital (KC11OIMI0441), and Yonsei University Severance Hospital (4-2011-0163). This study follows the guidelines of the 2008 Declaration of Helsinki.![]()
Both kidney failure and the composite of kidney failure and/or creatinine doubling were used as kidney outcomes. Kidney failure was defined as starting maintenance dialysis (required for longer than 3 months) or receiving kidney transplantation. Another outcome was the composite outcome of CVD and all-cause death. CVD was defined as any first event of the following that needed hospitalization, intervention, or therapy during the follow-up period : acute myocardial infarction, unstable angina which needed admission due to aggravated coronary ischemic symptoms, percutaneous coronary artery intervention or coronary bypass graft surgery, ischemic or hemorrhagic cerebral stroke, cerebral artery aneurysm, congestive heart failure, symptomatic arrhythmia, aggravated valvular heart meant by requiring hospital admission, any pericardial disease that required hospital admissions such as pericarditis, pericardial effusion, or cardiac tamponade, abdominal aortic aneurysm, or severe peripheral arterial disease (TableS1 ).
The chi-square test or Anova was used to compare the baseline characteristics. Non-normally distributed variables such as parathyroid hormone, urine protein/creatinine, and high sensitivity C-reactive protein were compared by Kruskal–Wallis test. The four groups had significant differences in baseline characteristics including age and baseline eGFR; we therefore used the overlap propensity score (PS) weighting method to minimize the effects of confounding factors on outcomes14 (link). Overlap weighting is a PS method that tries to mimic important attributes of randomized clinical trials. This method can overcome the potential limitation of adjusting the difference in measured characteristics using classic PS methods of inverse probability of treatment weighting (IPTW). Overlap weighting overcomes these limitations by assigning weights to each patient that are proportional to the probability of that patient belonging to the opposite group15 (link). PSs were calculated using a logistic model with the following variables since they showed significant differences among the four groups: age, sex, body mass index, CKD stage, mean blood pressure, CVD, hemoglobin, serum uric acid, calcium, phosphorous, albumin, total cholesterol, high-density lipoprotein, low-density lipoprotein, fasting blood sugar, intact parathyroid hormone, urine protein-to-creatinine ratio, high-sensitivity C-reactive protein, diuretics use, statin use, and angiotensin converting enzyme inhibitor or angiotensin receptor blocker use in this study. The log10 transformed values were used for PS calculation with the non-normally distributed variables such as parathyroid hormone, urine protein-to-creatinine ratio, and high sensitivity C-reactive protein. The patients in the compared group were weighted by the probability of the reference group (1-PS), and the patients in the reference group were weighted by the probability of the compared group (PS). For two groups of CKD causes, we applied the overlap weighting method to each set, resulting in a total of 6 sets. To visually compare distributions of balance, the density plots were created (FigureS1 ). Additionally, the standardized mean difference (SMD) was calculated to check good balance after the overlap weighting method was applied. This is calculated by the absolute value of the difference in mean among groups divided by the standard deviation. The SMD less than or equal to 0.10 means good balance after weighting15 (link). In outcome comparison analysis, a Cox proportional hazard model was used for kidney outcomes, and a cause-specific hazard model was used for the composite of CVD and death. In the competing risk model for the composite of CVD and death, kidney failure was considered a competing risk since many patients who started kidney replacement therapy were no longer followed for further event thereafter. Results are presented as hazard ratios (HRs) and 95% confidence intervals (95% CI). To estimate annual eGFR change, generalized linear mixed models were constructed with random intercepts and slopes with an unstructured model for the correlation structure. The results were expressed as estimates (standard errors). In the adjusted models, the variables used in PS score calculation were further adjusted. Spaghetti plots showing the individual trajectories of eGFR during follow-up were drawn to determine patterns of eGFR decline according to cause of CKD. P for the quadratic term was tested using polynomial mixed models with random intercepts and slopes. A P value less than 0.05 was considered statistically significant. SAS 9.4 (SAS Institute, Cary, NC, USA) and R version 3.5.3 (Foundation for Statistical Computing, Vienna, Austria) were used.
A total of 2238 patients enrolled in the study from April 2011 to February 2016. After excluding patients with unclassified etiology or without follow-up data, 2070 patients were finally analyzed in this study for survival analysis with follow up until March 31, 2020. To determine the annual eGFR change and trajectory, we included only those patients (n = 1952) with more than two creatinine measurements (Fig.
Flowchart of enrolled study patients. eGFR, estimated glomerular filtration rate; IDMS, isotope dilution mass spectrometry.
Both kidney failure and the composite of kidney failure and/or creatinine doubling were used as kidney outcomes. Kidney failure was defined as starting maintenance dialysis (required for longer than 3 months) or receiving kidney transplantation. Another outcome was the composite outcome of CVD and all-cause death. CVD was defined as any first event of the following that needed hospitalization, intervention, or therapy during the follow-up period : acute myocardial infarction, unstable angina which needed admission due to aggravated coronary ischemic symptoms, percutaneous coronary artery intervention or coronary bypass graft surgery, ischemic or hemorrhagic cerebral stroke, cerebral artery aneurysm, congestive heart failure, symptomatic arrhythmia, aggravated valvular heart meant by requiring hospital admission, any pericardial disease that required hospital admissions such as pericarditis, pericardial effusion, or cardiac tamponade, abdominal aortic aneurysm, or severe peripheral arterial disease (Table
The chi-square test or Anova was used to compare the baseline characteristics. Non-normally distributed variables such as parathyroid hormone, urine protein/creatinine, and high sensitivity C-reactive protein were compared by Kruskal–Wallis test. The four groups had significant differences in baseline characteristics including age and baseline eGFR; we therefore used the overlap propensity score (PS) weighting method to minimize the effects of confounding factors on outcomes14 (link). Overlap weighting is a PS method that tries to mimic important attributes of randomized clinical trials. This method can overcome the potential limitation of adjusting the difference in measured characteristics using classic PS methods of inverse probability of treatment weighting (IPTW). Overlap weighting overcomes these limitations by assigning weights to each patient that are proportional to the probability of that patient belonging to the opposite group15 (link). PSs were calculated using a logistic model with the following variables since they showed significant differences among the four groups: age, sex, body mass index, CKD stage, mean blood pressure, CVD, hemoglobin, serum uric acid, calcium, phosphorous, albumin, total cholesterol, high-density lipoprotein, low-density lipoprotein, fasting blood sugar, intact parathyroid hormone, urine protein-to-creatinine ratio, high-sensitivity C-reactive protein, diuretics use, statin use, and angiotensin converting enzyme inhibitor or angiotensin receptor blocker use in this study. The log10 transformed values were used for PS calculation with the non-normally distributed variables such as parathyroid hormone, urine protein-to-creatinine ratio, and high sensitivity C-reactive protein. The patients in the compared group were weighted by the probability of the reference group (1-PS), and the patients in the reference group were weighted by the probability of the compared group (PS). For two groups of CKD causes, we applied the overlap weighting method to each set, resulting in a total of 6 sets. To visually compare distributions of balance, the density plots were created (Figure
Adult
Albumins
Aneurysm
Angina, Unstable
Angiotensin-Converting Enzyme Inhibitors
Angiotensin Receptor Antagonists
Aortic Aneurysm, Abdominal
Arteries
Biopsy
Blood Glucose
Calcium
Cardiac Arrhythmia
Cardiac Tamponade
Cerebral Aneurysm
Cerebral Arteries
Cholesterol
Congestive Heart Failure
Coronary Artery Bypass Surgery
C Reactive Protein
Creatinine
Diabetes Mellitus, Non-Insulin-Dependent
Diabetic Nephropathy
Diabetic Retinopathy
Diagnosis
Dialysis
Diuretics
Effusion, Pericardial
EGFR protein, human
Ethics Committees, Research
Genetic Heterogeneity
Glomerular Filtration Rate
Glomerulonephritis
Glomerulosclerosis, Focal
Grafts
Heart
Heart Valves
Hematuria
Hemoglobin
Hemorrhage, Brain
High Blood Pressures
High Density Lipoproteins
Hospitalization
Hydroxymethylglutaryl-CoA Reductase Inhibitors
Hypertensive Nephropathy
IGA Glomerulonephritis
Immunosuppressive Agents
Index, Body Mass
Isotopes
Kidney
Kidney Failure
Kidney Glomerulus
Kidney Transplantation
Koreans
Low-Density Lipoproteins
Lupus Nephritis
Mass Spectrometry
Membranous Glomerulonephritis
Myocardial Infarction
Nephrosis, Lipoid
neuro-oncological ventral antigen 2, human
Parathyroid Hormone
Patients
Percutaneous Coronary Intervention
Pericarditis
Pericardium
Peripheral Vascular Diseases
Pharmaceutical Preparations
Phosphorus
Polycystic Kidney Diseases
Potter Type III Polycystic Kidney Disease
Proteins
Radioisotope Dilution Technique
Renal Replacement Therapy
Serum
Technique, Dilution
Therapeutics
Ultrasonography
Uric Acid
Urine
The primary outcome of the present study was the occurrence of cardiovascular death or myocardial infarction (MI) at 5 years. Secondary outcomes included cardiovascular death; all-cause death; MI; stroke; Bleeding Academic Research Consortium (BARC) type 3–5 bleeding; and a major adverse cardiovascular event (MACE) defined as a composite of cardiovascular death, MI, or stroke. All deaths were considered to be of cardiac origin unless a definite non-cardiac cause could be established. MI was defined as an elevated cardiac troponin or myocardial band fraction of creatine kinase greater than the upper reference limit with concomitant ischemic symptoms or electrocardiography findings indicative of ischemia. Procedure-related MI was not included in this definition of MI. Stroke was defined as any non-convulsive focal or global neurological deficit of abrupt onset caused by ischemia or hemorrhage within the brain.
Cardiovascular System
Cerebrovascular Accident
Electrocardiography
Heart
Hemorrhage, Brain
Ischemia
Isoenzyme CPK MB
Myocardial Infarction
Seizures, Focal
Troponin
Clinical data were obtained by outpatient clinic visits or telephone contact. An independent clinical event committee, whose members were unaware of clinical, echocardiographic, and physiologic data, adjudicated all events. For patients who were lost to follow‐up, mortality data with cause of death were confirmed by National Death Records. The primary end point was cardiovascular death or admission for HF. Secondary outcomes were all‐cause death, cardiovascular death, admission for HF, myocardial infarction (MI), any revascularization, and ischemic or hemorrhagic cerebrovascular accidents. All clinical outcomes were defined according to the Academic Research Consortium, including the addendum to the definition of MI. All deaths were considered cardiovascular unless a definitive noncardiovascular cause was identified. MI was defined as an elevation of creatine kinase–myocardial band or troponin level greater than the upper limit of normal with concomitant ischemic symptoms or electrocardiography findings indicative of ischemia. Admission for HF was defined as first hospitalization for HF. Hospitalization for HF should include all of the following criteria: (1) hospitalization with primary diagnosis of HF, (2) duration of hospitalization of at least 12 hours, (3) new or worsening symptoms of HF, (4) objective evidence of new or worsening HF on physical examination or laboratory findings, and (5) initiation or intensification of HF treatment.
Cardiovascular System
Clinic Visits
Diagnosis
Echocardiography
Electrocardiography
Hemorrhage, Brain
Hospitalization
Ischemia
Isoenzyme CPK MB
Myocardial Infarction
Patients
Physical Examination
physiology
Troponin
Hemorrhage in brain samples was measured by hematoxylin and eosin (H&E) staining. Three sections of each brain were used for H&E staining. Hematoxylin staining was performed for 5 min, and eosin staining was performed for 30 s. After image acquisition, ImageJ software (ImageJ, RRID: SCR _ 003,070) was used to analyze the amount and range of bleeding. The average value of three slices represents the bleeding condition of each tissue.
NISSL staining was used to assess the number of surviving neurons. After dewaxing, the sections were stained with toluidine blue dye at 60°C for 1 h and then washed in double distilled water for 5 min 3 times. The average number of surviving neurons in the sections was calculated to reflect neuronal damage.
NISSL staining was used to assess the number of surviving neurons. After dewaxing, the sections were stained with toluidine blue dye at 60°C for 1 h and then washed in double distilled water for 5 min 3 times. The average number of surviving neurons in the sections was calculated to reflect neuronal damage.
Afterimage
Blood Coagulation Disorders
Brain
Eosin
Hematoxylin
Hemorrhage, Brain
Neurons
Tissues
Tolonium Chloride
The proposed solution is trained and evaluated over the brain hemorrhage data of ICH patients, known as IHDC, which was made available in 2019 by the RSNA [2 (link),30 ,31 (link)]. The dataset is collected from three universities, which is further evaluated by about 60 radiologists of RSNA and made available to develop automated solutions for the detection and subtype classification of ICH [2 (link)]. The dataset consists of noncontrast head CT slices in digital imaging and communications in medicine (DICOM) annotated with IPH, IVH, SAH, SDH, and EDH. The slices that contain no hemorrhage or more than one are annotated as ‘Any’. The selected dataset for the training and validation of the proposed Res-Inc-LGBM solution includes information on 13,334 patients with different types of brain hemorrhages. The total number of brain CT images containing hemorrhage is 4579, as shown in Figure 2 . The general representation of subtypes of ICH is shown in Figure 3 . In addition, another dataset is employed to analyze the proposed solution’s generalisation ability, known as CQ500 [32 (link)]. It consists of head CT scans collected from different radiological centres, annotated by expert radiologists. Furthermore, detailed information about both datasets is given in Table 1 .
Brain
Fingers
Generalization, Psychological
Head
Hemorrhage
Hemorrhage, Brain
Patients
Radiography
Radiologist
X-Ray Computed Tomography
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More about "Hemorrhage, Brain"
Intracerebral Hemorrhage, ICH, Cerebral Bleeding, Brain Bleed, Intracranial Hemorrhage, Hemorrhagic Stroke, Hematoma, Traumatic Brain Injury, High Blood Pressure, Hypertension, Ruptured Blood Vessels, Aneurysm, Anticoagulants, Neuroimaging, Computed Tomography (CT), Magnetic Resonance Imaging (MRI), Cerebrovascular Accident (CVA), Paralysis, Seizures, Coma, Syngo.via, Bovine Serum Albumin (BSA), O-dianisidine, Ultravist 300, SAS 9.4, Isoflurane, Syngo CT Workplace 2012B, Somatom Definition Force, Infrared-Dyes-conjugated Secondary Antibodies, Rabbit Anti-β-actin.
Brain hemorrhage, also known as intracerebral hemorrhage (ICH), is a type of stroke caused by bleeding within the brain tissue.
It can result from various underlying conditions, such as high blood pressure (hypertension), trauma, or ruptured blood vessels (e.g., aneurysm).
Symptoms may include sudden severe headache, altered level of consciousness, nausea, vomiting, and paralysis.
Prompt medical intervention is crucial to minimize brain damage and improve outcomes.
Accurate diagnosis and treatment planning often require a careful review of relevant research protocols, including those from literature, preprints, and patents.
PubCompare.ai, an AI-driven platform, can help researchers easily locate and compare the best protocols to advance their brain hemorrhage studies, even with a hurman-like typo in the process.
Brain hemorrhage, also known as intracerebral hemorrhage (ICH), is a type of stroke caused by bleeding within the brain tissue.
It can result from various underlying conditions, such as high blood pressure (hypertension), trauma, or ruptured blood vessels (e.g., aneurysm).
Symptoms may include sudden severe headache, altered level of consciousness, nausea, vomiting, and paralysis.
Prompt medical intervention is crucial to minimize brain damage and improve outcomes.
Accurate diagnosis and treatment planning often require a careful review of relevant research protocols, including those from literature, preprints, and patents.
PubCompare.ai, an AI-driven platform, can help researchers easily locate and compare the best protocols to advance their brain hemorrhage studies, even with a hurman-like typo in the process.