Artificial-coloring in ultrasound-guided regional anesthesia
Yıl: 2023 Cilt: 35 Sayı: 1 Sayfa Aralığı: 10 - 15 Metin Dili: İngilizce DOI: 10.14744/agri.2021.25826 İndeks Tarihi: 06-06-2023
Artificial-coloring in ultrasound-guided regional anesthesia
Öz: Objectives: Ultrasonography (US) is an important visualization technique in regional anesthesia. Increasing in quality of images may lead to better conclusions. Our aim in this study was to evaluate the effect of artificial-coloring on image quality and practitioner’s preferences. Methods: Ultrasound images of five block regions, interscalene, supraclavicular, infraclavicular, femoral, and popliteal were taken on a volunteer using gray scale. Then, the images were colored in seven different color scales using artificial-coloring technique. All participants were asked to fill in the structured questionnaire. Results: All created images were assessed by three specialist and 14 resident anesthesiologists. The highest scores about nerve recognition, distinguishing nerve from surrounding tissues, and visual clarity of fascicles were obtained with blue scale images; however, these findings were not significant compared to gray scale (p>0.05). Blue scale was chosen as a favorite scale by 53% of participants. Conclusion: Increasing the image quality and resolution while performing regional anesthesia under ultrasound guidance increases success and reduces complications. Artificial-coloring is one of the adjustments that can improve image quality. In our study, the results of coloring with blue were remarkable. However, more importantly than the color chosen, we believe that routine adjustments such as gain, depth, and focusing will bring important advantages.
Anahtar Kelime: Ultrasonografi eşliğinde bölgesel anestezi sırasında yapay-renklendirme
Öz: Amaç: Ultrasonografi bölgesel anestezi sırasında kullanılan önemli bir görüntüleme tekniğidir. Görüntü kalitesinin artması sonuçları iyileştirir. Bu çalışmanın amacı, yapay renklendirmenin görüntü kalitesine ve uygulayıcı seçimlerine etkisini değerlendirmektir. Gereç ve Yöntem: İnterskalen, supraklaviküler, infraklaviküler, femoral ve popliteal bölge olmak üzere beş blok bölgesine ait ultrasonografi görüntüleri gri skalada alındı. Takiben görüntüler yapay renklendirme kullanılarak yedi farklı renge çevrilerek katılımcılar tarafından yapılandırılmış anket kullanılarak değerlendirildi. Bulgular: Görüntüler üç uzman ve 14 araştırma görevlisi tarafından değerlendirildi. Sinirin tanınması, çevre dokudan ayırt edilebilmesi ve fasiküllerin görülmesinin netliği hakkında en yüksek skor mavi skalayla oldu. Ancak bulgular gri skaladan istatistiksel olarak farklı değildi (p>0,05). Mavi skala katılımcıların %53’ü tarafından favori renk olarak tercih edildi. Sonuç: Ultrason eşliğinde bölgesel anestezi yapılırken görüntü kalitesi ve çözünürlüğün artması başarıyı artırır, komplikasyonları azaltır. Yapay renklendirme görüntü kalitesini artırabilecek ayarlamalardan biridir. Çalışmamızda mavi renk ile renklendirmenin sonuçları dikkat çekiciydi. Ancak, seçilen renkten daha önemlisi bu ayarın kazanç, derinlik ve odaklama gibi rutin yapılmasının önemli avantajları da beraberinde getireceği kanaatindeyiz.
Anahtar Kelime: Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık
- 1. Marhofer P, Greher M, Kapral S. Ultrasound guidance in regional anaesthesia. Br J Anaesth 2005;94:7–17. [CrossRef ]
- 2. Barrington MJ, Kluger R. Ultrasound guidance reduces the risk of local anesthetic systemic toxicity following peripheral nerve blockade. Reg Anesth Pain Med 2013;38:289–99.
- 3. Swenson JD, Davis JJ, DeCou JA. A novel approach for assessing catheter position after ultrasound-guided placement of continuous interscalene block. Anesth Analg 2008;106:1015–6. [CrossRef ]
- 4. Yamamoto H, Sakura S, Wada M, Shido A. A prospective, randomized comparison between single- and multipleinjection techniques for ultrasound-guided subgluteal sciatic nerve block. Anesth Analg 2014;119:1442–8. [CrossRef ]
- 5. Clendenen NJ, Robards CB, Clendenen SR. A standardized method for 4D ultrasound-guided peripheral nerve blockade and catheter placement. Biomed Res Int 2014;2014:920538. [CrossRef ]
- 6. Clendenen SR, Robards CB, Clendenen NJ, Freidenstein JE, Greengrass RA. Real-time 3-dimensional ultrasound-assisted infraclavicular brachial plexus catheter placement: Implications of a new technology. Anesthesiol Res Pract 2010;2010:208025. [CrossRef ]
- 7. Choquet O, Capdevila X. Case report: Three-dimensional high-resolution ultrasound-guided nerve blocks: A new panoramic vision of local anesthetic spread and perineural catheter tip location. Anesth Analg 2013;116:1176–81.
- 8. Zander D, Hüske S, Hoffmann B, Cui XW, Dong Y, Lim A, et al. Ultrasound image optimization (“Knobology”): B-mode. Ultrasound Int Open 2020;6:E14–24. [CrossRef ]
- 9. Ault MJ, Rosen BT. Portable ultrasound: The next generation arrives. Crit Ultrasound J 2010;2:39–42. [CrossRef ]
- 10. Akelma FK, Altinsoy S, Akkus IB, Aslan H, Ergil J. Evaluation of the attitudes of anesthesiologists to the use of clinical ultrasonography. JARSS [Article in Turkish] 2019;27:258– 64.
- 11. Bainbridge D, McConnell B, Royse C. A review of diagnostic accuracy and clinical impact from the focused use of perioperative ultrasound. Can J Anaesth 2018;65:371–80.
- 12. Asztalos IB, Colling CA, Buchner AM, Chandrasekhara V. Development of a narrow-band imaging classification to reduce the need for routine biopsies of gastric polyps. Gastroenterol Rep (Oxf ) 2020;9:219–25. [CrossRef ]
- 13. McQueen AS, Bhatia KS. Thyroid nodule ultrasound: Technical advances and future horizons. Insights Imaging 2015;6:173–88. [CrossRef ]
- 14. Arbabi A, Kai J, Khan AR, Baron CA. Diffusion dispersion imaging: Mapping oscillating gradient spin-echo frequency dependence in the human brain. Magn Reson Med 2020;83:2197–208. [CrossRef ]
| APA | Araz C, Yavuz G, Kuş A (2023). Artificial-coloring in ultrasound-guided regional anesthesia. , 10 - 15. 10.14744/agri.2021.25826 |
| Chicago | Araz Coskun,Yavuz Gürkan,Kuş Alparslan Artificial-coloring in ultrasound-guided regional anesthesia. (2023): 10 - 15. 10.14744/agri.2021.25826 |
| MLA | Araz Coskun,Yavuz Gürkan,Kuş Alparslan Artificial-coloring in ultrasound-guided regional anesthesia. , 2023, ss.10 - 15. 10.14744/agri.2021.25826 |
| AMA | Araz C,Yavuz G,Kuş A Artificial-coloring in ultrasound-guided regional anesthesia. . 2023; 10 - 15. 10.14744/agri.2021.25826 |
| Vancouver | Araz C,Yavuz G,Kuş A Artificial-coloring in ultrasound-guided regional anesthesia. . 2023; 10 - 15. 10.14744/agri.2021.25826 |
| IEEE | Araz C,Yavuz G,Kuş A "Artificial-coloring in ultrasound-guided regional anesthesia." , ss.10 - 15, 2023. 10.14744/agri.2021.25826 |
| ISNAD | Araz, Coskun vd. "Artificial-coloring in ultrasound-guided regional anesthesia". (2023), 10-15. https://doi.org/10.14744/agri.2021.25826 |
| APA | Araz C, Yavuz G, Kuş A (2023). Artificial-coloring in ultrasound-guided regional anesthesia. Ağrı, 35(1), 10 - 15. 10.14744/agri.2021.25826 |
| Chicago | Araz Coskun,Yavuz Gürkan,Kuş Alparslan Artificial-coloring in ultrasound-guided regional anesthesia. Ağrı 35, no.1 (2023): 10 - 15. 10.14744/agri.2021.25826 |
| MLA | Araz Coskun,Yavuz Gürkan,Kuş Alparslan Artificial-coloring in ultrasound-guided regional anesthesia. Ağrı, vol.35, no.1, 2023, ss.10 - 15. 10.14744/agri.2021.25826 |
| AMA | Araz C,Yavuz G,Kuş A Artificial-coloring in ultrasound-guided regional anesthesia. Ağrı. 2023; 35(1): 10 - 15. 10.14744/agri.2021.25826 |
| Vancouver | Araz C,Yavuz G,Kuş A Artificial-coloring in ultrasound-guided regional anesthesia. Ağrı. 2023; 35(1): 10 - 15. 10.14744/agri.2021.25826 |
| IEEE | Araz C,Yavuz G,Kuş A "Artificial-coloring in ultrasound-guided regional anesthesia." Ağrı, 35, ss.10 - 15, 2023. 10.14744/agri.2021.25826 |
| ISNAD | Araz, Coskun vd. "Artificial-coloring in ultrasound-guided regional anesthesia". Ağrı 35/1 (2023), 10-15. https://doi.org/10.14744/agri.2021.25826 |
