1.Parent artery encroachment after clipping of kissing middle cerebral artery bifurcation aneurysm: A case report
Changheon KIM ; HyoJun KIM ; Taesik SONG ; Seung Kon HUH
Journal of Cerebrovascular and Endovascular Neurosurgery 2026;28(1):77-82
Background:
Kissing middle cerebral artery bifurcation aneurysms (KMCBA) are rare vascular lesions. Their complex morphology and limited surgical experience may predispose patients to devastating complications.Cases: Among 100 patients who underwent microsurgical clipping for cerebral aneurysms between May 2022 and April 2025, two were diagnosed with unruptured KMCBA. In Case 1, the two aneurysm sacs of a left KMCBA were clipped separately using interlocking and fenestrated clips without premature rupture. In Case 2, both aneurysm sacs of a right KMCBA were clipped simultaneously with a long J-shaped clip. Postoperatively, the patient developed left hemiparesis due to clip-induced encroachment of the superior trunk of M2. Revision clipping with a shorter L-shaped clip restored flow, and the patient was discharged with a modified Rankin scale (mRS) score of 4.
Conclusions
Successful microsurgical clipping of KMCBA requires meticulous surgical strategies to avoid parent artery encroachment, including separate clipping of each aneurysm neck whenever feasible, appropriate clip selection, and the use of multimodal intraoperative anatomical and physiological monitoring.
2.Improvement of antioxidant activities of persimmon peel extraction through green extraction technology
Yueun JEONG ; Changheon LEE ; Jeong-Jin SEO ; Kyeonghwan HWANG ; Sumin KIM ; Daeung YU
Journal of Nutrition and Health 2024;57(6):560-566
Purpose:
This study aimed to improve the antioxidant activities of sweet persimmon peel extracts using supercritical carbon dioxide (SFE-CO2 ) as a green extraction (GE) technology, as part of upcycling efforts. It also aimed to demonstrate the effectiveness of GE as an ecofriendly extraction method by comparing it with conventional extraction (CE) techniques.
Methods:
Sweet persimmon peel extracts were obtained using CE (hot water at 80°C for 6 h or 95% ethanol at room temperature for 24 hours) and SFE-CO2 extraction (50°C for 2 hours, with pressures ranging from 100 to 250 bar). Antioxidant activities (2,2-diphenyl-1-picrylhydrazyl [DPPH] radical scavenging activity and tannin content) were analyzed to evaluate and compare the antioxidant extraction efficiency across different extraction methods.
Results:
In the CE extraction method, the 95% ethanol extract exhibited 1.2 times higher DPPH radical scavenging activity and 1.5 times higher tannin content than that of the hot water extract. In the SFE-CO2 extraction method, antioxidant activities increased with increasing pressure (100–250 bar), as higher pressures enhanced antioxidant activities and extraction efficiency. At 250 bar, the SFE-CO2 extracts demonstrated 1.6 times higher DPPH radical scavenging activity and 2.0 times higher tannin content than that of the hot water extract, and 1.3 times higher DPPH scavenging activity and tannin content than that of the 95% ethanol extract. These findings highlight the superior efficiency of extraction using the SFE-CO2 method.
Conclusion
This study demonstrated that SFE-CO2 was an efficient and eco-friendly method for extracting antioxidants from sweet persimmon peels, surpassing conventional methods.It underscores the potential of SFE-CO2 for the sustainable upcycling of sweet persimmon byproducts and the promotion of green technologies to enhance antioxidant activities.
3.Improvement of antioxidant activities of persimmon peel extraction through green extraction technology
Yueun JEONG ; Changheon LEE ; Jeong-Jin SEO ; Kyeonghwan HWANG ; Sumin KIM ; Daeung YU
Journal of Nutrition and Health 2024;57(6):560-566
Purpose:
This study aimed to improve the antioxidant activities of sweet persimmon peel extracts using supercritical carbon dioxide (SFE-CO2 ) as a green extraction (GE) technology, as part of upcycling efforts. It also aimed to demonstrate the effectiveness of GE as an ecofriendly extraction method by comparing it with conventional extraction (CE) techniques.
Methods:
Sweet persimmon peel extracts were obtained using CE (hot water at 80°C for 6 h or 95% ethanol at room temperature for 24 hours) and SFE-CO2 extraction (50°C for 2 hours, with pressures ranging from 100 to 250 bar). Antioxidant activities (2,2-diphenyl-1-picrylhydrazyl [DPPH] radical scavenging activity and tannin content) were analyzed to evaluate and compare the antioxidant extraction efficiency across different extraction methods.
Results:
In the CE extraction method, the 95% ethanol extract exhibited 1.2 times higher DPPH radical scavenging activity and 1.5 times higher tannin content than that of the hot water extract. In the SFE-CO2 extraction method, antioxidant activities increased with increasing pressure (100–250 bar), as higher pressures enhanced antioxidant activities and extraction efficiency. At 250 bar, the SFE-CO2 extracts demonstrated 1.6 times higher DPPH radical scavenging activity and 2.0 times higher tannin content than that of the hot water extract, and 1.3 times higher DPPH scavenging activity and tannin content than that of the 95% ethanol extract. These findings highlight the superior efficiency of extraction using the SFE-CO2 method.
Conclusion
This study demonstrated that SFE-CO2 was an efficient and eco-friendly method for extracting antioxidants from sweet persimmon peels, surpassing conventional methods.It underscores the potential of SFE-CO2 for the sustainable upcycling of sweet persimmon byproducts and the promotion of green technologies to enhance antioxidant activities.
4.Improvement of antioxidant activities of persimmon peel extraction through green extraction technology
Yueun JEONG ; Changheon LEE ; Jeong-Jin SEO ; Kyeonghwan HWANG ; Sumin KIM ; Daeung YU
Journal of Nutrition and Health 2024;57(6):560-566
Purpose:
This study aimed to improve the antioxidant activities of sweet persimmon peel extracts using supercritical carbon dioxide (SFE-CO2 ) as a green extraction (GE) technology, as part of upcycling efforts. It also aimed to demonstrate the effectiveness of GE as an ecofriendly extraction method by comparing it with conventional extraction (CE) techniques.
Methods:
Sweet persimmon peel extracts were obtained using CE (hot water at 80°C for 6 h or 95% ethanol at room temperature for 24 hours) and SFE-CO2 extraction (50°C for 2 hours, with pressures ranging from 100 to 250 bar). Antioxidant activities (2,2-diphenyl-1-picrylhydrazyl [DPPH] radical scavenging activity and tannin content) were analyzed to evaluate and compare the antioxidant extraction efficiency across different extraction methods.
Results:
In the CE extraction method, the 95% ethanol extract exhibited 1.2 times higher DPPH radical scavenging activity and 1.5 times higher tannin content than that of the hot water extract. In the SFE-CO2 extraction method, antioxidant activities increased with increasing pressure (100–250 bar), as higher pressures enhanced antioxidant activities and extraction efficiency. At 250 bar, the SFE-CO2 extracts demonstrated 1.6 times higher DPPH radical scavenging activity and 2.0 times higher tannin content than that of the hot water extract, and 1.3 times higher DPPH scavenging activity and tannin content than that of the 95% ethanol extract. These findings highlight the superior efficiency of extraction using the SFE-CO2 method.
Conclusion
This study demonstrated that SFE-CO2 was an efficient and eco-friendly method for extracting antioxidants from sweet persimmon peels, surpassing conventional methods.It underscores the potential of SFE-CO2 for the sustainable upcycling of sweet persimmon byproducts and the promotion of green technologies to enhance antioxidant activities.

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