Your search keyword '"Trimmel NE"' showing total 2 results

1. A Soft Robotic Actuator System for In Vivo Modeling of Normal Pressure Hydrocephalus.

Author

Flurenbrock F, Rosalia L, Podgorsak A, Sapozhnikov K, Trimmel NE, Weisskopf M, Oertel MF, Roche E, Zeilinger MN, Korn L, and Daners MS

Subjects

Humans, Animals, Sheep, Blood Pressure, Heart Rate, Intracranial Pressure physiology, Hydrocephalus, Normal Pressure, Robotics, Hydrocephalus surgery

Abstract

Objective: The intracranial pressure (ICP) affects the dynamics of cerebrospinal fluid (CSF) and its waveform contains information that is of clinical importance in medical conditions such as hydrocephalus. Active manipulation of the ICP waveform could enable the investigation of pathophysiological processes altering CSF dynamics and driving hydrocephalus., Methods: A soft robotic actuator system for intracranial pulse pressure amplification was developed to model normal pressure hydrocephalus in vivo. Different end actuators were designed for intraventricular implantation and manufactured by applying cyclic tensile loading on soft rubber tubing. Their mechanical properties were investigated, and the type that achieved the greatest pulse pressure amplification in an in vitro simulator of CSF dynamics was selected for application in vivo. A hydraulic actuation device based on a linear voice coil motor was developed to enable automated and fast operation of the end actuators. The combined system was validated in an acute ovine pilot in vivo study., Results: in vitro results show that variations in the used materials and manufacturing settings altered the end actuator's dynamic properties, such as the pressure-volume characteristics. In the in vivo model, a cardiac-gated actuation volume of 0.125 mL at a heart rate of 62 bpm caused an increase of 205% in mean peak-to-peak amplitude but only an increase of 1.3% in mean ICP., Conclusion: The introduced soft robotic actuator system is capable of ICP waveform manipulation., Significance: Continuous amplification of the intracranial pulse pressure could enable in vivo modeling of normal pressure hydrocephalus and shunt system testing under pathophysiological conditions to improve therapy for hydrocephalus.

Published

2024

2. Toward the "Perfect" Shunt: Historical Vignette, Current Efforts, and Future Directions.

Author

Podgoršak A, Flürenbrock F, Trimmel NE, Korn L, Oertel MF, Stieglitz L, Fernandes Dias S, Hierweger MM, Zeilinger M, Weisskopf M, and Schmid Daners M

Subjects

Humans, Child, Ambulatory Care Facilities, Behavior Therapy, Catheters, Prostheses and Implants, Hydrocephalus surgery

Abstract

As a concept, drainage of excess fluid volume in the cranium has been around for more than 1000 years. Starting with the original decompression-trepanation of Abulcasis to modern programmable shunt systems, to other nonshunt-based treatments such as endoscopic third ventriculostomy and choroid plexus cauterization, we have come far as a field. However, there are still fundamental limitations that shunts have yet to overcome: namely posture-induced over- and underdrainage, the continual need for valve opening pressure especially in pediatric cases, and the failure to reinstall physiologic intracranial pressure dynamics. However, there are groups worldwide, in the clinic, in industry, and in academia, that are trying to ameliorate the current state of the technology within hydrocephalus treatment. This chapter aims to provide a historical overview of hydrocephalus, current challenges in shunt design, what members of the community have done and continue to do to address these challenges, and finally, a definition of the "perfect" shunt is provided and how the authors are working toward it., (© 2024. The Author(s), under exclusive license to Springer Nature Switzerland AG.)

Published

2024