基本情報
- 所属
- 自治医科大学 麻酔科学・集中治療医学講座 助教
- 学位
- 公衆衛生学修士(2023年5月)
- ORCID ID
- https://orcid.org/0000-0002-7437-9979
- J-GLOBAL ID
- 202101009153023523
- researchmap会員ID
- R000019995
研究分野
1経歴
6-
2023年10月 - 現在
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2021年5月 - 2023年9月
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2016年4月 - 2021年5月
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2014年4月 - 2016年3月
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2013年4月 - 2014年3月
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2011年4月 - 2013年3月
学歴
1-
2005年4月 - 2011年3月
委員歴
1論文
16-
JA clinical reports 10(1) 65-65 2024年10月15日 査読有り責任著者BACKGROUND: Interatrial right-to-left shunt flow through a patent foramen ovale (PFO) can be caused by changes in heart position for anastomosis during off-pump coronary artery bypass (OPCAB). We herein present a case in which the direction of PFO shunt flow changed with heart position during OPCAB and the ventilation settings after sternal closure. CASE PRESENTATION: A 66-year-old man with interstitial pneumonia underwent OPCAB. Preoperative transesophageal echocardiography revealed right-to-left shunt flow through a PFO induced by the Valsalva maneuver. During OPCAB, heart displacement resulted in right-to-left shunting and acute hypoxemia, which quickly improved with increase of inspired oxygen fraction. After chest closure, bidirectional shunt flow developed under increased airway pressure. CONCLUSIONS: Vigilant intraoperative monitoring with TEE and postoperative airway pressure management are important to address shunt flow and hypoxemia due to PFO.
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General thoracic and cardiovascular surgery 2024年7月17日 査読有り筆頭著者OBJECTIVE: Systemic heparinization during cardiopulmonary bypass (CPB) can significantly affect thromboelastography (TEG). This study investigated the feasibility of adding protamine in vitro to allow assessment of coagulation status using the TEG 6s system during CPB. METHODS: In this prospective observational study, 21 patients undergoing elective cardiac valve surgery were evaluated. During CPB, protamine was added in vitro to the heparinized blood of these patients at a concentration of 0.05 mg/mL and analyzed with the TEG 6s (Pre). The TEG parameters were compared to those analyzed after CPB withdrawal and systemic protamine administration (Post). RESULTS: The citrated kaolin maximal amplitude (CK-MA) and the citrated functional fibrinogen maximal amplitude (CFF-MA) exhibited strong correlations between Pre and Post measurements (r = 0.790 and 0.974, respectively, P < 0.001 for both), despite significant mean differences (-2.23 mm for CK-MA and -0.68 mm for CFF-MA). Bland-Altman analysis showed a clinically acceptable agreement between Pre and Post measurement of CK-MA and CFF-MA (the percentage error was 10.6% and 12.2%, respectively). In contrast, the citrated kaolin reaction time (CK-R) showed no significant correlation between Pre and Post measurements (r = 0.328, P = 0.146), with a mean difference of 1.42 min (95% CI: -0.45 to 3.29). CONCLUSIONS: In vitro protamine addition allows assessment of coagulation status during CPB using the TEG 6s system. CK-MA and CFF-MA measured during CPB using this method revealed a strong correlation and agreement with post-CPB measurements, suggesting that our method potentially facilitates early prediction of post-CPB coagulation status and decision-making on transfusion strategies. CLINICAL TRIAL REGISTRATION: The study was registered in the University Hospital Medical Information Network Clinical Trials Registry (UMIN-CTR, registration number: UMIN000041097, date of registration: July 13, 2020, https://center6.umin.ac.jp/cgi-open-bin/ctr_e/ctr_view.cgi?recptno=R000046925 ) before the recruitment of participants.
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Cureus 16(6) e62370 2024年6月14日 査読有り責任著者
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BMC anesthesiology 24(1) 88-88 2024年3月2日 査読有り責任著者BACKGROUND: Tracking preload dependency non-invasively to maintain adequate tissue perfusion in the perioperative period can be challenging.The effect of phenylephrine on stroke volume is dependent upon preload. Changes in stroke volume induced by phenylephrine administration can be used to predict preload dependency. The change in the peripheral perfusion index derived from photoplethysmography signals reportedly corresponds with changes in stroke volume in situations such as body position changes in the operating room. Thus, the peripheral perfusion index can be used as a non-invasive potential alternative to stroke volume to predict preload dependency. Herein, we aimed to determine whether changes in perfusion index induced by the administration of phenylephrine could be used to predict preload dependency. METHODS: We conducted a prospective single-centre observational study. The haemodynamic parameters and perfusion index were recorded before and 1 and 2 min after administering 0.1 mg of phenylephrine during post-induction hypotension in patients scheduled to undergo surgery. Preload dependency was defined as a stroke volume variation of ≥ 12% before phenylephrine administration at a mean arterial pressure of < 65 mmHg. Patients were divided into four groups according to total peripheral resistance and preload dependency. RESULTS: Forty-two patients were included in this study. The stroke volume in patients with preload dependency (n = 23) increased after phenylephrine administration. However, phenylephrine administration did not impact the stroke volume in patients without preload dependency (n = 19). The perfusion index decreased regardless of preload dependency. The changes in the perfusion index after phenylephrine administration exhibited low accuracy for predicting preload dependency. Based on subgroup analysis, patients with high total peripheral resistance tended to exhibit increased stroke volume following phenylephrine administration, which was particularly prominent in patients with high total peripheral resistance and preload dependency. CONCLUSION: The findings of the current study revealed that changes in the perfusion index induced by administering 0.1 mg of phenylephrine could not predict preload dependency. This may be attributed to the different phenylephrine-induced stroke volume patterns observed in patients according to the degree of total peripheral resistance and preload dependency. TRIAL REGISTRATION: University Hospital Medical Information Network (UMIN000049994 on 9/01/2023).
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Journal of Cardiothoracic and Vascular Anesthesia 38(2) 394-402 2024年2月 査読有り筆頭著者
MISC
34-
LiSA 31(3) 290-295 2024年3月<文献概要>ここまで,ICU領域で蓄積されてきた人工呼吸管理の考え方や理論について学んできた。ICUと手術室での人工呼吸管理について考えてみると,鎮静の深さ,筋弛緩薬使用の有無,自発呼吸との同調考慮,呼吸管理の時間などが挙げられる。また,そもそもICU患者のほうが酸素化・換気の問題を抱えていたり,循環動態が不安定であったりと患者層にも違いがある。一方で,非生理学的な呼吸様式を強いる人工呼吸管理は必要悪であり,人工呼吸による弊害,いわゆる人工呼吸器関連肺傷害ventilator-associated lung injury(VALI)を最小限にしようとする目的は,手術室でもICUでも共通している。本稿では,麻酔科医がICUでの人工呼吸管理を勉強した際に,それがどのように手術室での麻酔に活かせるのかを考えていく。