| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Qiwei Xiao, Alister J Bates, Denis J Doorl. Effects of decongestion on nasal cavity air conditioning efficiency: a CFD cohort study. Scientific reports. vol 14. issue 1. 2024-04-11. PMID:38605156. |
effects of decongestion on nasal cavity air conditioning efficiency: a cfd cohort study. |
2024-04-11 |
2024-04-14 |
human |
| Sverre Gullikstad Johnse. Computational Rhinology: Unraveling Discrepancies between In Silico and In Vivo Nasal Airflow Assessments for Enhanced Clinical Decision Support. Bioengineering (Basel, Switzerland). vol 11. issue 3. 2024-03-27. PMID:38534513. |
this paper consists of three distinct parts-an introduction to and review of the field of computational rhinology, a review of the published literature on in vitro and in silico studies of nasal airflow, and the presentation and analysis of previously unpublished high-fidelity cfd simulation data of in silico rhinomanometry. |
2024-03-27 |
2024-03-29 |
Not clear |
| M A Burgos, Lina Rosique, F Piqueras, C García-Navalón, M A Sevilla-García, D Hellín, F Esteba. Reducing variability in nasal surgery outcomes through computational fluid dynamics and advanced 3D virtual surgery techniques. Heliyon. vol 10. issue 5. 2024-03-11. PMID:38463850. |
this study aims to delineate the specific impact of using computational fluid dynamics (cfd) and 3d virtual surgery techniques in otolaryngology surgery, focusing on their roles in enhancing the precision of nasal surgery and optimizing future patient outcomes. |
2024-03-11 |
2024-03-14 |
Not clear |
| Wenting Xie, Lu Zhang, Jiayi Shao, Chunxiang Zhang, Zhongfang Zhang, Linkun Zhan. Respiratory Fluid Mechanics of the Effect of Mouth Breathing on High-Arched Palate: Computational Fluid Dynamics Analyses. The Journal of craniofacial surgery. 2023-07-10. PMID:37427957. |
cfd can be used to simulate the stress on the oral and nasal surfaces of the palate under different breathing patterns. |
2023-07-10 |
2023-08-14 |
human |
| Jaakko Ormiskangas, Olli Valtonen, Teemu Harju, Markus Rautiainen, Ilkka Kivekä. Computational fluid dynamics calculations in inferior turbinate surgery: a cohort study. European archives of oto-rhino-laryngology : official journal of the European Federation of Oto-Rhino-Laryngological Societies (EUFOS) : affiliated with the German Society for Oto-Rhino-Laryngology - Head and Neck Surgery. 2023-06-21. PMID:37341759. |
to investigate how the results of nasal computational fluid dynamics (cfd) simulations change due to inferior turbinate surgery and how the results correlate with patient specific subjective assessment and volumetric results in the nasal cavities. |
2023-06-21 |
2023-08-14 |
Not clear |
| Xing Jin, Yi Lu, Xiang Ren, Sheng Guo, Darui Jin, Bo Liu, Xiangzhi Bai, Junxiu Li. Exploring the influence of nasal vestibule structure on nasal obstruction using CFD and Machine Learning method. Medical engineering & physics. vol 117. 2023-06-18. PMID:37331745. |
exploring the influence of nasal vestibule structure on nasal obstruction using cfd and machine learning method. |
2023-06-18 |
2023-08-14 |
Not clear |
| Xing Jin, Yi Lu, Xiang Ren, Sheng Guo, Darui Jin, Bo Liu, Xiangzhi Bai, Junxiu Li. Exploring the influence of nasal vestibule structure on nasal obstruction using CFD and Machine Learning method. Medical engineering & physics. vol 117. 2023-06-18. PMID:37331745. |
motivated by clinical findings about the nasal vestibule, this study analyzes the aerodynamic characteristics of the nasal vestibule and attempt to determine anatomical features which have a large influence on airflow through a combination of computational fluid dynamics (cfd) and machine learning method. |
2023-06-18 |
2023-08-14 |
Not clear |
| Xing Jin, Yi Lu, Xiang Ren, Sheng Guo, Darui Jin, Bo Liu, Xiangzhi Bai, Junxiu Li. Exploring the influence of nasal vestibule structure on nasal obstruction using CFD and Machine Learning method. Medical engineering & physics. vol 117. 2023-06-18. PMID:37331745. |
firstly, the aerodynamic characteristics of the nasal vestibule are detailedly analyzed using the cfd method. |
2023-06-18 |
2023-08-14 |
Not clear |
| Xing Jin, Yi Lu, Xiang Ren, Sheng Guo, Darui Jin, Bo Liu, Xiangzhi Bai, Junxiu Li. Exploring the influence of nasal vestibule structure on nasal obstruction using CFD and Machine Learning method. Medical engineering & physics. vol 117. 2023-06-18. PMID:37331745. |
based on cfd simulation results, we divide the nasal vestibule into two types with distinctly different airflow patterns, which is consistent with clinical findings. |
2023-06-18 |
2023-08-14 |
Not clear |
| Richard Tjahjono, Hana Salati, Kiao Inthavong, Narinder Sing. Correlation of Nasal Mucosal Temperature and Nasal Patency-A Computational Fluid Dynamics Study. The Laryngoscope. vol 133. issue 6. 2023-05-09. PMID:37158263. |
this study examines the role of nasal mucosal temperature in the perception of nasal patency using in vivo and computational fluid dynamics (cfd) measurements. |
2023-05-09 |
2023-08-14 |
Not clear |
| Robert Chrzan, Joanna Szaleniec, Krzysztof Karbowski, Bartosz Kopiczak, Jolanta Gawlik, Jerzy Tomik, Tadeusz Popiel. Virtual rhinomanometry based on computed tomography of the paranasal sinuses in patients with nasal septum deviation a pilot study. Otolaryngologia polska = The Polish otolaryngology. vol 77. issue 1. 2023-02-22. PMID:36805513. |
the aim of the study was to compare the flow disturbances in computational fluid dynamics (cfd) technique based on computed tomography (ct) to the results of active anterior rhinomanometry (rmm), in patients with nasal septum deviation (nsd). |
2023-02-22 |
2023-08-14 |
Not clear |
| Marek Plášek, Michaela Masárová, Marián Bojko, Pavel Komínek, Petr Matoušek, Martin Formáne. Computational Fluid Dynamics Could Enable Individualized Surgical Treatment of Nasal Obstruction (A Preliminary Study). Diagnostics (Basel, Switzerland). vol 12. issue 11. 2022-11-11. PMID:36359486. |
the present study aimed to create a cfd nasal airflow model to determine the major routes of airflow through the nasal cavity and thus help with individualization of surgical treatment of nasal disorders. |
2022-11-11 |
2023-08-14 |
Not clear |
| Marek Plášek, Michaela Masárová, Marián Bojko, Pavel Komínek, Petr Matoušek, Martin Formáne. Computational Fluid Dynamics Could Enable Individualized Surgical Treatment of Nasal Obstruction (A Preliminary Study). Diagnostics (Basel, Switzerland). vol 12. issue 11. 2022-11-11. PMID:36359486. |
cfd surgical planning could enable individualized precise surgical treatment of nasal disorders. |
2022-11-11 |
2023-08-14 |
Not clear |
| C E Zambon, G B Cherobin, E R Utumi, G G Machado, F A F de Vasconcellos, M P S M Peres, R R M Pilan, R L Voegels, F R Pinn. Computational fluid dynamics and NOSE scale to assess nasal respiratory function, and correlation with linear maxillary measurements after surgically assisted rapid maxillary expansion. International journal of oral and maxillofacial surgery. 2022-11-01. PMID:36319581. |
the aim of this study was to determine the variation in nasal airway resistance in adult patients with a transverse maxillary deficiency before and after surgically assisted rapid maxillary expansion (sarme) by computational fluid dynamics (cfd) using computed tomography scans, and to correlate this variation with maxillary linear measurements obtained by means of plaster models. |
2022-11-01 |
2023-08-14 |
Not clear |
| Hana Salati, Narinder Singh, Mehrdad Khamooshi, Sara Vahaji, David F Fletcher, Kiao Inthavon. Nasal Irrigation Delivery in Three Post-FESS Models From a Squeeze-bottle Using CFD. Pharmaceutical research. 2022-09-02. PMID:36056272. |
nasal irrigation delivery in three post-fess models from a squeeze-bottle using cfd. |
2022-09-02 |
2023-08-14 |
Not clear |
| Bryce Noblitt, John Higgins, Katherine Kopytek, Christoph Brehm, Nikita Gupt. The Effect of Segmentation Threshold on Computational Fluid Dynamic Analysis of Nasal Airflow. The Journal of craniofacial surgery. 2022-08-31. PMID:36044319. |
the objective analysis of nasal airflow stands to benefit greatly from the adoption of computational fluid dynamic (cfd) methodologies. |
2022-08-31 |
2023-08-14 |
Not clear |
| Gerallt Williams, Julie D Suma. In Vitro Anatomical Models for Nasal Drug Delivery. Pharmaceutics. vol 14. issue 7. 2022-07-27. PMID:35890249. |
in silico, cfd simulation or other new developments may in future, with suitable validation, present additional approaches to current modelling, although the complexity and wide degree of variability in nasal anatomy will remain a challenge. |
2022-07-27 |
2023-08-14 |
human |
| Sara Vahaji, Jingliang Dong, Lin Tian, Jiyuan T. Interspecies comparison of heat and mass transfer characteristics in monkey and human nasal cavities. Computers in biology and medicine. vol 147. 2022-06-06. PMID:35667153. |
this paper provides a comparative study between two monkey and two human nasal subjects under the same ambient temperature and humidity conditions, where nasal models were reconstructed from ct images and the heat and mass transfer process incorporating with the intricate nose anatomy were modelled by the computational fluid dynamics (cfd) approach. |
2022-06-06 |
2023-08-14 |
human |
| Arun V Kolanjiyil, Ali Alfaifi, Ghali Aladwani, Laleh Golshahi, Worth Longes. Importance of Spray-Wall Interaction and Post-Deposition Liquid Motion in the Transport and Delivery of Pharmaceutical Nasal Sprays. Pharmaceutics. vol 14. issue 5. 2022-05-28. PMID:35631539. |
hence, an updated cfd framework with a new spray-wall interaction (swi) model in tandem with a post-deposition liquid motion (pdlm) model was developed and applied to evaluate nasal spray delivery for flonase and flonase sensimist products. |
2022-05-28 |
2023-08-13 |
Not clear |
| Arun V Kolanjiyil, Ali Alfaifi, Ghali Aladwani, Laleh Golshahi, Worth Longes. Importance of Spray-Wall Interaction and Post-Deposition Liquid Motion in the Transport and Delivery of Pharmaceutical Nasal Sprays. Pharmaceutics. vol 14. issue 5. 2022-05-28. PMID:35631539. |
for both nasal spray products, cfd revealed significant effects of the spray momentum on surface liquid motion, as well as motion of the surface film due to airflow generated shear stress and gravity. |
2022-05-28 |
2023-08-13 |
Not clear |