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Juliane Mayer

Frau M.Sc.

Wissenschaftliche Mitarbeiterin, Studiengangskoordination und Fachstudienberatung B.Sc. Medizintechnik
Institut für Medizingerätetechnik

Kontakt

+49 711 685 61695
E-Mail

Pfaffenwaldring 9
70569 Stuttgart
Deutschland
Raum: 3.207

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Es können auch individuelle Termine für telefonische oder Video-Sprechstunden vereinbart werden (Webex oder alfaview).

Publikationen

J. Mayer, H. Schittenhelm, and P. P. Pott, “Opportunities and challenges of implementing circular economy in the medical device sector in germany,” Sustainable Production and Consumption, Apr. 2025, doi: 10.1016/j.spc.2025.04.014.
- BibTeX
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BibTeX
@article{Mayer_2025, author = {Mayer, Juliane and Schittenhelm, Helena and Pott, Peter P.}, doi = {10.1016/j.spc.2025.04.014}, issn = {2352-5509}, journal = {Sustainable Production and Consumption}, month = {04}, publisher = {Elsevier BV}, title = {Opportunities and challenges of implementing circular economy in the medical device sector in germany}, url = {http://dx.doi.org/10.1016/j.spc.2025.04.014}, year = 2025 }
Link
http://dx.doi.org/10.1016/j.spc.2025.04.014
J. Mayer, B. T. Steinbrenner, and P. P. Pott, “Shape-locked Geometry Reduces Snapping Effects in Concentric Tube Robots,” in Proceedings of the 16th Hamlyn Symposium on Medical Robotics 2024, Proceedings of the 16th Hamlyn Symposium on Medical Robotics 2024 Imperial College London and the Royal Geographical Society, London, United Kingdom, 2024, vol. 16, pp. 55–56. [Online]. Available: https://www.hamlynsymposium.org/proceedings/
- BibTeX
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BibTeX
@inproceedings{mayer2024shapelocked, author = {Mayer, Juliane and Steinbrenner, Björn T. and Pott, Peter P.}, eventdate = {25.-28.06.24}, eventtitle = {The Hamlyn Symposium on Medical Robotics 2024}, journal = {Proceedings of the 16th Hamlyn Symposium on Medical Robotics 2024}, pages = {55-56}, publisher = {The Hamlyn Centre Imperial College London}, title = {Shape-locked Geometry Reduces Snapping Effects in Concentric Tube Robots}, url = {https://www.hamlynsymposium.org/proceedings/}, venue = {Proceedings of the 16th Hamlyn Symposium on Medical Robotics 2024 Imperial College London and the Royal Geographical Society, London, United Kingdom}, volume = 16, year = 2024 }
Link
https://www.hamlynsymposium.org/proceedings/
M. Hutter, J. Mayer, M. B. Schäfer, P. P. Pott, and B. Gundelsweiler, “Potential of magnetic shape memory alloys in medical applications,” in Current Directions in Biomedical Engineering, Stuttgar, 2024, vol. 10, pp. 336–339. doi: doi:10.1515/cdbme-2024-2082.
- BibTeX
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BibTeX
@inproceedings{HutterMayerSchäferPottGundelsweiler+2024+336+339, author = {Hutter, Marco and Mayer, Juliane and Schäfer, Max B. and Pott, Peter P. and Gundelsweiler, Bernd}, doi = {doi:10.1515/cdbme-2024-2082}, eventdate = {18.-20.09.2024}, eventtitle = {BMT 2024}, journal = {Current Directions in Biomedical Engineering}, number = 4, pages = {336--339}, title = {Potential of magnetic shape memory alloys in medical applications}, url = {https://doi.org/10.1515/cdbme-2024-2082}, venue = {Stuttgar}, volume = 10, year = 2024 }
Link
https://doi.org/10.1515/cdbme-2024-2082
J. Mayer, M. Dumancic, and P. P. Pott, “Symmetric single-input eccentric tube robot (ETR) for manual use,” in Current Directions in Biomedical Engineering, Basel, 2024, vol. 10, pp. 103–106. doi: https://doi.org/10.1515/cdbme-2024-1078.
- BibTeX
BibTeX
@inproceedings{mayer2024symmetric, author = {Mayer, Juliane and Dumancic, Marcel and Pott, Peter P.}, doi = {https://doi.org/10.1515/cdbme-2024-1078}, eventdate = {24.-26.08.2023}, eventtitle = {CURAC 2023}, journal = {Current Directions in Biomedical Engineering}, number = 2, pages = {103-106}, publisher = {De Gruyter}, title = {Symmetric single-input eccentric tube robot (ETR) for manual use}, venue = {Basel}, volume = 10, year = 2024 }
J. Mayer, F. Bajraktari, J. Liu, and P. P. Pott, “Technik für die sanfte Blutentnahme,” mt medizintechnik, vol. 144, Art. no. 3, 2024, [Online]. Available: https://www.mt-medizintechnik.de
- BibTeX
- Link
BibTeX
@article{mayer2024technik, author = {Mayer, Juliane and Bajraktari, Flakë and Liu, Jan and Pott, Peter P.}, issn = {0344-9416}, journal = {mt medizintechnik}, language = {german}, number = 3, pages = {30-33}, publisher = {TÜV Media}, title = {Technik für die sanfte Blutentnahme}, url = {https://www.mt-medizintechnik.de}, volume = 144, year = 2024 }
Link
https://www.mt-medizintechnik.de
G. A. Giacoppo, J. Mayer, J. Hartmann, A. L. Bachmann, and P. P. Pott, “Actively shielded capacitive proximity sensor for endoscopy,” in Current Directions in Biomedical Engineering, Duisburg, 2023, vol. 9, pp. 93–96. doi: doi:10.1515/cdbme-2023-1024.
- BibTeX
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BibTeX
@inproceedings{GiacoppoMayerHartmannBachmannPott+2023+93+96, author = {Giacoppo, Giuliano A. and Mayer, Juliane and Hartmann, Julien and Bachmann, Ada L. and Pott, Peter P.}, doi = {doi:10.1515/cdbme-2023-1024}, eventtitle = {BMT 2023}, journal = {Current Directions in Biomedical Engineering}, number = 1, pages = {93--96}, title = {Actively shielded capacitive proximity sensor for endoscopy}, url = {https://doi.org/10.1515/cdbme-2023-1024}, venue = {Duisburg}, volume = 9, year = 2023 }
Link
https://doi.org/10.1515/cdbme-2023-1024
J. Mayer, J. Narr, and P. P. Pott, “Towards non-invasive Wilson’s disease progression monitoring based on corneal copper content,” in Current Directions in Biomedical Engineering, Duisburg, 2023, vol. 9, pp. 266–269. doi: doi:10.1515/cdbme-2023-1067.
- BibTeX
- Link
BibTeX
@inproceedings{MayerNarrPott+2023+266+269, author = {Mayer, Juliane and Narr, Julia and Pott, Peter P.}, doi = {doi:10.1515/cdbme-2023-1067}, eventtitle = {BMT 2023}, journal = {Current Directions in Biomedical Engineering}, number = 1, pages = {266--269}, title = {Towards non-invasive Wilson’s disease progression monitoring based on corneal copper content}, url = {https://doi.org/10.1515/cdbme-2023-1067}, venue = {Duisburg}, volume = 9, year = 2023 }
Link
https://doi.org/10.1515/cdbme-2023-1067
G. A. Giacoppo, J. Meiringer, M. B. Schäfer, J. Mayer, M. da Silva, L. Finke, and P. P. Pott, “Influence of a fixed twisting zone on Twisted String Actuation,” Mannheim, Jun. 2022.
- BibTeX
BibTeX
@inproceedings{giacoppo2022influence, author = {Giacoppo, Giuliano A and Meiringer, Johannes and Schäfer, Max B and Mayer, Juliane and da Silva, Michael and Finke, Lars and Pott, Peter P}, booktitle = {ACTUATOR22}, eventdate = {29.-30.06.2022}, eventtitle = {ACTUATOR22}, month = {06}, title = {Influence of a fixed twisting zone on Twisted String Actuation}, venue = {Mannheim}, year = 2022 }
J. Mayer, M. B. Schäfer, J. Liu, G. A. Giacoppo, T. Markert, S. Matich, P. Brunner, and P. P. Pott, “Hand-Held Device for Force Estimation during Tool-Tissue Interaction,” Mannheim, Jun. 2022.
- Zusammenfassung
- BibTeX
Zusammenfassung
When manipulating tissue during medical interventions, high-accuracy movements are important to avoid injuries. However, feedback is limited and it is hard to establish control loops to ensure correct movements. We propose the use of a novel highly compact 6-axis force / torque sensor (Ø 10.5 mm x 11.0 mm) within a hand piece to determine low forces and torques during various small-scale procedures including gentle tool-tissue interaction. For a first validation of the system, different venepuncture cannulas were connected to the sensor top and driven into skinned fruits (toma-toes and grapes) as well as into a silicone block. During insertion of the needle tips, maximum forces of 74 – 158 mN (tomato) and 51 - 161 mN (grape) were recorded, and steadily increasing forces in the range of 0 – 250 mN when insert-ing needles 7.5 mm into silicone. For a 0.99 g screw nut (9.73 mN), the measured gravitational force was 10.6 ± 1.5 mN during ten measurement sets. During the insertion, needle torques of up to 9.5 mNm were observed. Different cutting phases were seen similar to the phases during needle penetration testing. We conclude that the compact measurement setup used is suitable to measure the low forces and torques occurring when cutting soft, aqueous human tissues with or without skin-like layers.
BibTeX
@inproceedings{mayer2022handheld, abstract = {When manipulating tissue during medical interventions, high-accuracy movements are important to avoid injuries. However, feedback is limited and it is hard to establish control loops to ensure correct movements. We propose the use of a novel highly compact 6-axis force / torque sensor (Ø 10.5 mm x 11.0 mm) within a hand piece to determine low forces and torques during various small-scale procedures including gentle tool-tissue interaction. For a first validation of the system, different venepuncture cannulas were connected to the sensor top and driven into skinned fruits (toma-toes and grapes) as well as into a silicone block. During insertion of the needle tips, maximum forces of 74 – 158 mN (tomato) and 51 - 161 mN (grape) were recorded, and steadily increasing forces in the range of 0 – 250 mN when insert-ing needles 7.5 mm into silicone. For a 0.99 g screw nut (9.73 mN), the measured gravitational force was 10.6 ± 1.5 mN during ten measurement sets. During the insertion, needle torques of up to 9.5 mNm were observed. Different cutting phases were seen similar to the phases during needle penetration testing. We conclude that the compact measurement setup used is suitable to measure the low forces and torques occurring when cutting soft, aqueous human tissues with or without skin-like layers.}, author = {Mayer, Juliane and Schäfer, Max B. and Liu, Jan and Giacoppo, Giuliano A. and Markert, Timo and Matich, Sebastian and Brunner, Pascal and Pott, Peter P.}, booktitle = {Proceedings of the ACTUATOR22}, eventdate = {29.-30.06.2022}, eventtitle = {ACTUATOR22}, month = {06}, title = {Hand-Held Device for Force Estimation during Tool-Tissue Interaction}, venue = {Mannheim}, year = 2022 }
J. Mayer, P. Junger, L. Hokenmaier, and P. P. Pott, “Wearable Wake-up System for CCHS Patients,” Current Directions in Biomedical Engineering, vol. 8, Art. no. 2, 2022, doi: doi:10.1515/cdbme-2022-1063.
- BibTeX
- Link
BibTeX
@article{MayerJungerHokenmaierPott+2022+245+248, author = {Mayer, Juliane and Junger, Philipp and Hokenmaier, Lukas and Pott, Peter P.}, doi = {doi:10.1515/cdbme-2022-1063}, journal = {Current Directions in Biomedical Engineering}, number = 2, pages = {245--248}, title = {Wearable Wake-up System for CCHS Patients}, url = {https://doi.org/10.1515/cdbme-2022-1063}, volume = 8, year = 2022 }
Link
https://doi.org/10.1515/cdbme-2022-1063
L. E. Eisenhardt, J. Mayer, and P. P. Pott, “Development of an app-controlled simple, wearable teeth grinding sensing device,” Current Directions in Biomedical Engineering, 2021.
- Zusammenfassung
- BibTeX
Zusammenfassung
Teeth grinding is, due to its various impacts on the human body, a highly discussed issue in dentistry. It can damage the tooth structure or cause pain due to muscle tension. At the moment, there is neither a satisfactory diagnostic nor a comprehensive treatment option. This paper deals with the development of an app-controlled, small, portable sensor unit that can be used by patients to monitor their teeth grinding in everyday life. It also offers a treatment option due to an implemented biofeedback option. To achieve the most cost-effective device possible, only off-theshelf electronics and no proprietary software were used. In initial tests, the measuring device showed high level of measurement accuracy when performing measurements without feedback at rest (f_score=-0.025...0).
BibTeX
@article{eisenhardt2021development, abstract = {Teeth grinding is, due to its various impacts on the human body, a highly discussed issue in dentistry. It can damage the tooth structure or cause pain due to muscle tension. At the moment, there is neither a satisfactory diagnostic nor a comprehensive treatment option. This paper deals with the development of an app-controlled, small, portable sensor unit that can be used by patients to monitor their teeth grinding in everyday life. It also offers a treatment option due to an implemented biofeedback option. To achieve the most cost-effective device possible, only off-theshelf electronics and no proprietary software were used. In initial tests, the measuring device showed high level of measurement accuracy when performing measurements without feedback at rest (f_score=-0.025...0).}, author = {Eisenhardt, Laura E and Mayer, Juliane and Pott, Peter Paul}, journal = {Current Directions in Biomedical Engineering}, title = {Development of an app-controlled simple, wearable teeth grinding sensing device}, year = 2021 }

Lehre

Lebenslauf

2016 Abschluss B.Sc. Medizintechnik der Eberhard Karls Universität Tübingen und der Universität Stuttgart

2019 Abschluss M.Sc. Medizintechnik der Universität Stuttgart

heute Wissenschaftliche Mitarbeiterin am Institut für Medizingerätetechnik der Universität Stuttgart

Betreute Abschlussarbeiten

Medizinrobotik: Concentric und Eccentric Tube Robots

BA0272 Friction reduction through dithering in CTRs. Institut für Medizingerätetechnik, Universität Stuttgart. 2024.

FA0271 Reduktion der Torsion in CTR durch magnetische Führung. Institut für Medizingerätetechnik, Universität Stuttgart. 2024.

BA0256 Using flexible shafts in ETRs to reduce storage of torsional energy. Institut für Medizingerätetechnik, Universität Stuttgart. 2024.

FA0255 Finite element simulation of interlocking polygonal concentric tubes during rotation. Institut für Medizingerätetechnik, Universität Stuttgart. 2024.

FA0243 Simulation of the motions of a Concentric Tube Robot using SOFA. Institut für Medizingerätetechnik, Universität Stuttgart. 2024.

BA0229 Eccentric Tube Robot mit formschlüssigem Schaft zur Verringerung von Torsion. Institut für Medizingerätetechnik, Universität Stuttgart. 2023.

BA0213 Untersuchung des Torsionsverhaltens von Concentric Tube Robots mit eckigem Querschnitt. Institut für Medizingerätetechnik, Universität Stuttgart. 2023.

MA0208 Gestalterische Möglichkeiten für Concentric Tube Robots aus Kunststoff. Institut für Medizingerätetechnik, Universität Stuttgart. 2023.

MA0204 Entwicklung eines bionischen Endeffektors aus Eccentric Tube Robots. Institut für Medizingerätetechnik, Universität Stuttgart. 2023.

BA0143 Control of a versatile drive unit for super elastic end effectors. Institut für Medizingerätetechnik, Universität Stuttgart. 2021.

BA0106 Konzeption einer vielseitigen Antriebs- und Steuerungseinheit für superelastische Endeffektoren. Institut für Medizingerätetechnik, Universität Stuttgart. 2021.

Medizinrobotik: Einsatz in der minimalinvasiven Chirurgie

FA0267 Miniaturisierung von Granular Jamming Grippern für die minimalinvasive Chirurgie. Institut für Medizingerätetechnik, Universität Stuttgart. 2024.

FA0266 Entwicklung eines handgehaltenen Sensorsystems zur Aufzeichnung von Interaktionskräften in der Ophthalmochirurgie. Institut für Medizingerätetechnik, Universität Stuttgart. 2024.

SA0178 Entwicklung und Validierung eines kapazitiven Näherungssensors für die Endorobotik. Institut für Medizingerätetechnik, Universität Stuttgart. 2022.

Wearables für Diagnostik

MA0181 Usability-Studie zu einem mobilen Wecksystem für CCHS-Betroffene. Institut für Medizingerätetechnik, Universität Stuttgart. 2023.

SA0182 Detektion von Kayser-Fleischer-Ringen bei Morbus Wilson. Institut für Medizingerätetechnik, Universität Stuttgart. 2022.

MA0144 Usability-Verbesserung und Studien-Design für ein mobiles Wecksystem. Institut für Medizingerätetechnik, Universität Stuttgart. 2022.

MA0102 Entwicklung einer mobilen Sensoreinheit zum Erkennen von unbewusstem Zähneknirschen. Institut für Medizingerätetechnik, Universität Stuttgart. 2021.

D4C: Kreislaufwirtschaft in der Medizintechnik

MA0200 Untersuchung des Potenzials zur Reduzierung des Ressourcenverbrauchs in der Medizintechnik. Institut für Medizingerätetechnik, Universität Stuttgart. 2023.

Juliane Mayer

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