1.A case of pulmonary barotrauma complicated with cerebral arterial air embolism in a diver.
Chinese Journal of Industrial Hygiene and Occupational Diseases 2021;39(7):538-539
Pulmonary barotrauma is a kind of disease caused by the injury of lung tissue or blood vessel when the gas pressure of lung is too high or too lower than the external pressure of the body, which causes the air to enter the blood vessel and adjacent tissue. It could be happened in the escape of the divers with the light diving equipment or the sailors from submarine. Generally, the decompression chamber was used to treating the disease, and the minimum air pressure of 0.5 MPa recompression therapeutic schedule was used to selecting. In November 2019, a patient with pulmonary barotrauma combined with cerebral arterial gas embolism caused by improper underwater escape with light diving equipment was admitted to the General Hospital of Eastern War Zone. He was treated with 0.12 MPa oxygen inhalation recompression scheme in the oxygen chamber pressurized with air. 7 days later, the patient recovered and discharged.
Barotrauma/complications*
;
Decompression Sickness/complications*
;
Diving/adverse effects*
;
Embolism, Air/etiology*
;
Humans
;
Lung Injury
;
Male
2.Air Embolism during Upper Endoscopy: A Case Report
Yin FANG ; Junbei WU ; Feng WANG ; Lihong CHENG ; Yunhong LU ; Xiaofei CAO
Clinical Endoscopy 2019;52(4):365-368
Air embolism is a rare complication of upper endoscopy and potentially causes life-threatening events. A 67-year-old man with a history of surgery of cardiac carcinoma and pancreatic neuroendocrine tumor underwent painless upper endoscopy because of tarry stools. During the procedure, air embolism developed, which caused decreased pulse oxygen saturation and delayed sedation recovery. He recovered with some weakness of the left upper limb in the intensive care unit without hyperbaric oxygen therapy. The etiology, clinical manifestations, and treatments of air embolism are discussed based on the literature reports. Although air embolism is uncommon in endoscopic examinations, the patients’ outcomes could be improved if clinicians are alert to this potential complication, and promptly start proper diagnostic and therapeutic measures.
Aged
;
Embolism, Air
;
Endoscopy
;
Heart Neoplasms
;
Humans
;
Hyperbaric Oxygenation
;
Intensive Care Units
;
Neuroendocrine Tumors
;
Oxygen
;
Upper Extremity
3.Cerebral Air Embolism Observed on Susceptibility-Weighted Magnetic Resonance Imaging
Sukmin LEE ; Myungjun LEE ; Gha Hyun LEE
Journal of the Korean Neurological Association 2019;37(3):314-315
No abstract available.
Embolism, Air
;
Magnetic Resonance Imaging
4.Cerebral Air Embolism: a Case Report with an Emphasis of its Pathophysiology and MRI Findings
Se Ri KANG ; See Sung CHOI ; Se Jeong JEON
Investigative Magnetic Resonance Imaging 2019;23(1):70-74
Cerebral air embolism (CAE) is a rare complication of various medical procedures. It manifests with symptoms similar to those of typical acute cerebral infarction, however the treatment is quite different. We present a case of arterial CAE that was associated with a disconnected central venous catheter and appeared as punctate dark signal intensities with aliasing artifacts on the susceptibility-weighted filtered phase magnetic resonance image. The susceptibility-weighted filtered phase image can be helpful for diagnosing CAE and the magnetic resonance imaging reflects the pathophysiology of CAE.
Artifacts
;
Central Venous Catheters
;
Cerebral Infarction
;
Embolism, Air
;
Intracranial Embolism
;
Magnetic Resonance Imaging
5.Efficiency of Air Bubble Removal in Preparation of Low-Profile Angioplasty Balloon Catheter: Bench-Top Comparison of Six Methods
Joon Ho CHOI ; Seon Moon HWANG ; Deok Hee LEE
Neurointervention 2019;14(1):27-34
PURPOSE: Complete removal of air bubbles from balloons for neurovascular angioplasty is cumbersome. We compared the preparation difficulty, air removal efficiency, and air collection pattern of six different balloon catheter preparation methods to propose a better preparation method for both initial and second balloon uses, especially for small-profile angioplasty balloon catheters. MATERIALS AND METHODS: A total of 18 neurovascular angioplasty balloon catheters with nominal diameters of 2 mm were prepared to test six different preparation methods: the instruction for use method (method A), simplified method using a syringe (method B) and four newly devised preparation methods using inflating devices (methods C–F). Serial radiographs were obtained while the balloons were gradually inflated. We measured the time for each preparation and the bubble number, analyzed their distribution in the balloon, and calculated the contrast filling ratio (contrast filling area/total balloon area) for initial and second ballooning. The whole process was repeated three times. RESULTS: The preparation time varied widely (11.5 seconds [method D] to 73.3 seconds [method A]). On initial inflation, the contrast filling ratio at 8 atm was the highest (100%) with methods A and F. On second inflation, the ratio was again highest with method A (99.5%), followed by method F (99.2%). Initial ballooning tended to show a uniform pattern of single bubble in the distal segment of the balloon; in contrast, second ballooning showed varying patterns in which the bubbles were multiple and randomly distributed. CONCLUSION: None of the six methods were able to completely exclude air bubbles from the balloon catheters including the second ballooning; however, the method of repeating aspiration with high-volume inflating device (method F) could be a practical option considering the simplicity and efficiency of preparation.
Angioplasty
;
Angioplasty, Balloon
;
Catheters
;
Clothing
;
Embolism, Air
;
Equipment Failure
;
Inflation, Economic
;
Intracranial Arteriosclerosis
;
Methods
;
Syringes
7.Cerebral air embolism treated using hyperbaric oxygen therapy
Yeon Jung KIM ; Sang Beom JEON
Journal of Neurocritical Care 2019;12(1):64-65
No abstract available.
Embolism, Air
;
Hyperbaric Oxygenation
8.Status epilepticus due to cerebral air embolism after the Valsalva maneuver
Hyun Ji LYOU ; Hye Jeong LEE ; Grace Yoojin LEE ; Won Joo KIM
Journal of Neurocritical Care 2019;12(1):51-54
BACKGROUND: Cerebral air embolism is uncommon but potentially causes catastrophic events such as cardiac damage or even death. However, due to a low overall incidence, it may go undiagnosed. CASE REPORT: A 56-year-old man with a medical history of right upper lobectomy due to lung cancer showed changes in mental status after the Valsalva maneuver, followed by status epilepticus during admission. Brain and chest computed tomography showed cerebral air embolism and accidental pneumothorax in the right major fissure. After antiepileptic drug infusion and oxygen therapy, he recovered completely. CONCLUSION: Since cerebral air embolism may result in fatal outcomes, it should be suspected in patients with sudden neurological deterioration after routine medical procedures.
Brain
;
Embolism, Air
;
Fatal Outcome
;
Humans
;
Incidence
;
Lung Neoplasms
;
Middle Aged
;
Oxygen
;
Pneumothorax
;
Status Epilepticus
;
Thorax
;
Valsalva Maneuver
10.Prediction of air inflow during central venous catheter insertion: experimental study.
Hyo Jae JUNG ; Yang Weon KIM ; Chang Min PARK ; Chul Ho PARK ; Ji Hun KANG ; Yoo Sang YOON
Journal of the Korean Society of Emergency Medicine 2018;29(6):641-648
OBJECTIVE: This study examined the incidence and amount of air inflow during central venous catheter (CVC) insertion. METHODS: This study was an experimental study aimed at designing an apparatus to implement blood vessel and blood flow in the human body. A 1.5-m long core tube with a Teflon tube, suction rubber tube, and polyvinyl chloride tube were made. This core tube was assumed to be the blood vessel of the human body. Blood was replaced with a saline solution. The saline solution was placed higher than the core tube and flowed into the inside of the tube by gravity. The CVC was injected 15-cm deep into the core tube. The air was collected through a 3-way valve into the upper tube. The experiments were carried out by differentiating the pressure in the tube, CVC insertion step, and diameter of the end of the catheter. The experiment was repeated 10 times under the same conditions. RESULTS: The amount of air decreased with increasing pressure applied to the tube. Air was not generated when the syringe needle was injected, and the amount of air increased with increasing size of the distal end catheter. CONCLUSION: To minimize the possibility of air embolism, it is necessary to close the distal end catheter at the earliest point as soon as possible.
Blood Vessels
;
Catheters
;
Central Venous Catheters*
;
Embolism, Air
;
Gravitation
;
Human Body
;
Incidence
;
Jugular Veins
;
Needles
;
Polytetrafluoroethylene
;
Polyvinyl Chloride
;
Rubber
;
Sodium Chloride
;
Suction
;
Syringes

Result Analysis
Print
Save
E-mail