Ex vivo modeling of the airflow dynamics and two-and three-dimensional biomechanical effects of suture placements for prosthetic laryngoplasty in horses

Nicola P. Lynch 1Department of Veterinary Clinical Sciences, Royal Veterinary College, University of London, North Mymms, Herfordshire, AL9 7TA, England.

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Sarah A. Jones 1Department of Veterinary Clinical Sciences, Royal Veterinary College, University of London, North Mymms, Herfordshire, AL9 7TA, England.

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Lucy G. Bazley-White 1Department of Veterinary Clinical Sciences, Royal Veterinary College, University of London, North Mymms, Herfordshire, AL9 7TA, England.

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Zoe F. Wilson 1Department of Veterinary Clinical Sciences, Royal Veterinary College, University of London, North Mymms, Herfordshire, AL9 7TA, England.

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Jennifer Raffetto 1Department of Veterinary Clinical Sciences, Royal Veterinary College, University of London, North Mymms, Herfordshire, AL9 7TA, England.

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Thilo Pfau 1Department of Veterinary Clinical Sciences, Royal Veterinary College, University of London, North Mymms, Herfordshire, AL9 7TA, England.

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Jonathon Cheetham 2Department of Clinical Sciences, College of Veterinary Medicine, Cornell University, Ithaca, NY 14853.

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Justin D. Perkins 1Department of Veterinary Clinical Sciences, Royal Veterinary College, University of London, North Mymms, Herfordshire, AL9 7TA, England.

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Abstract

OBJECTIVE

To identify the degree of left arytenoid cartilage (LAC) abduction that allows laryngeal airflow similar to that in galloping horses, assess 2-D and 3-D biomechanical effects of prosthetic laryngoplasty on LAC movement and airflow, and determine the influence of suture position through the muscular process of the arytenoid cartilage (MPA) on these variables.

SAMPLE

7 equine cadaver larynges.

PROCEDURES

With the right arytenoid cartilage maximally abducted and inspiratory airflow simulated by vacuum, laryngeal airflow and translaryngeal pressure and impedance were measured at 12 incremental LAC abduction forces (0% to 100% [maximum abduction]) applied through laryngoplasty sutures passed caudocranially or mediolaterally through the left MPA. Cross-sectional area of the rima glottis and left-to-right angle quotient were determined from photographs at each abduction force; CT images were obtained at alternate forces. Arytenoid and cricoid cartilage markers allowed calculation of LAC roll, pitch, and yaw through use of Euler angles on 3-D reconstructed CT images.

RESULTS

Translaryngeal pressure and impedance decreased, and airflow increased rapidly at low abduction forces, then slowed until a plateau was reached at approximately 50% of maximum abduction force. The greatest LAC motion was rocking (pitch). Suture position through the left MPA did not significantly affect airflow data. Approximately 50% of maximum abduction force, corresponding to a left arytenoid angle of approximately 30° and left-to-right angle quotient of 0.79 to 0.84, allowed airflow of approximately 61 ± 6.5 L/s.

CONCLUSIONS AND CLINICAL RELEVANCE

Ex vivo modeling results suggested little benefit to LAC abduction forces > 50%, which allowed airflow similar to that reported elsewhere for galloping horses.

Abstract

OBJECTIVE

To identify the degree of left arytenoid cartilage (LAC) abduction that allows laryngeal airflow similar to that in galloping horses, assess 2-D and 3-D biomechanical effects of prosthetic laryngoplasty on LAC movement and airflow, and determine the influence of suture position through the muscular process of the arytenoid cartilage (MPA) on these variables.

SAMPLE

7 equine cadaver larynges.

PROCEDURES

With the right arytenoid cartilage maximally abducted and inspiratory airflow simulated by vacuum, laryngeal airflow and translaryngeal pressure and impedance were measured at 12 incremental LAC abduction forces (0% to 100% [maximum abduction]) applied through laryngoplasty sutures passed caudocranially or mediolaterally through the left MPA. Cross-sectional area of the rima glottis and left-to-right angle quotient were determined from photographs at each abduction force; CT images were obtained at alternate forces. Arytenoid and cricoid cartilage markers allowed calculation of LAC roll, pitch, and yaw through use of Euler angles on 3-D reconstructed CT images.

RESULTS

Translaryngeal pressure and impedance decreased, and airflow increased rapidly at low abduction forces, then slowed until a plateau was reached at approximately 50% of maximum abduction force. The greatest LAC motion was rocking (pitch). Suture position through the left MPA did not significantly affect airflow data. Approximately 50% of maximum abduction force, corresponding to a left arytenoid angle of approximately 30° and left-to-right angle quotient of 0.79 to 0.84, allowed airflow of approximately 61 ± 6.5 L/s.

CONCLUSIONS AND CLINICAL RELEVANCE

Ex vivo modeling results suggested little benefit to LAC abduction forces > 50%, which allowed airflow similar to that reported elsewhere for galloping horses.

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