{"id":6445,"date":"2021-05-22T13:52:00","date_gmt":"2021-05-22T11:52:00","guid":{"rendered":"https:\/\/acmit.at\/referenzen\/"},"modified":"2025-07-04T16:50:40","modified_gmt":"2025-07-04T14:50:40","slug":"referenzen","status":"publish","type":"page","link":"https:\/\/acmit.at\/de\/referenzen\/","title":{"rendered":"Referenzen"},"content":{"rendered":"\n\n\t\t\t

Abschlussarbeiten<\/h3>\n\t\t\t\t

Die folgenden Doktor-, Master- und Bachelorthesen werden\/wurden am Kompetenzzentrum ACMIT und\/oder deren wissenschaftlichen und betrieblichen Partnern verfasst.<\/p>\n\t\t\t\t\t\t

PhD-Arbeiten<\/h4>\n\t\t\t

F. Adebayo (in progress), „AI Methods for Tissue Analytics“<\/p>\n

S. Akhter (in progress), „Objective Assessment of Donning and Doffing Surgical Gloves“<\/p>\n

S. Aljomaa (in progress), „Objective Assessment of Donning and Doffing Surgical Gloves“<\/p>\n

C. Barr (in progress), „Ultrasound Guidance in Neurosurgery“<\/p>\n

A. Borji (in progress), „Image-Derived AI-Based Methods to Support Treatment Decision-Making for Pediatric Osteosarcoma Patients“<\/p>\n

L. Conolly (in progress), „Robotic Breast Conserving Surgery“<\/p>\n

R. Hisey (in progress), „Surgical Workflow Analysis“<\/p>\n

H. Marton (in progress), „In Vitro Investigation of Lesions Created during Radiofrequency Ablation of Atrial Fibrillation“<\/p>\n

K. M\u00f3ga (in progress), „VR\/AR\/MR Enhanced Non-Technical Support in Surgery“<\/p>\n

E. J. Muniya (in progress), „AI Based Point-Cloud Non-Rigid Registration Methods for Soft Tissue“<\/p>\n

T. D. Nagy (in progress), „Methodological Approach for Subtask Automation in Robot-Assisted Minimally Invasive Surgery“<\/p>\n

N. Saidi (in progress), „Image Retrieval and Classification in Radiological Images Using Graph Neural Networks“<\/p>\n

I. SM. Ragib Shahriar (in progress), „Optimized Trajectories for Interventional Imaging for Dentistry and Medicine Applications“<\/p>\n

C. Yeung (in progress), „Intraoperative Breast Cancer Segmentation in Ultrasound“<\/p>\n

P. Nasute (2024), „Breast Cancer Surgery Outcome Analysis“<\/p>\n

O. Aryeetey (2024), „Development of 3D Printable Tissue-Mimicking Meta-Materials for Functional Anatomical Models“<\/p>\n

M. de Vries (2023), „Steerable Needles in Prostate Brachytherapy: From Sketch to MDR-Compliant Batch“<\/p>\n

L. Jaksa (2023), „Development of an Additive Manufacturing System for Producing Tissue-Mimicking Materials“<\/p>\n

R. Levendovics (2023), „Endoscopic Image and Kinematic Data-Based Autonomous Technical and Non-Technical Skill Assessment in Robot-Assisted Minimally Invasive Surgery“<\/p>\n

S. Estermann (2021), „Development of a Process for Reproducing Biological Tissues in Terms of Their Mechanical Properties by Means of 3D Printing“<\/p>\n

S. Hatamikia (2021), „Patient Specific Source-Detector Trajectory Optimization for Cone Beam Computed Tomography“<\/p>\n

F. Jel\u00ednek (2015), „Steering and Harvesting Technology for Minimally Invasive Biopsy“<\/p>\n

D. Puchberger (2015), „Novel Sensor System for Integrated Wound Monitoring Methods“<\/p>\n

T. Haidegger (2011), „Theory and Method to Enhance Computer-Integrated Surgical Systems“<\/p>\n\t\t\t\t\t\t

Master-Arbeiten<\/h4>\n\t\t\t

N. Ansems (in progress), „Advancing Fetoscopic Repair of Complex Gastroschisis: Proof of Principle for a Novel Closure Method Using a Silicone Ring with Membrane“<\/p>\n

T. van Deudekom (in progress), „Reducing Occupational Radiation Exposure in Cardiac Catheterisation Laboratories: Dose Rate Predictions and Feedback Strategies“<\/p>\n

T. Elliott (in progress), „AI-Based Analysis of Mass Spectrometry Tissue Analytics“<\/p>\n

K. Hara-Lee (in progress), „Robot-Assisted Breast Conserving Surgery“<\/p>\n

R. Incze (in progress), „Point of Care Ultrasound Protocols in the Management of Covid“<\/p>\n

R. Jadadic (in progress), „The Volumetric Measurement of Periapical Lesions in CBCT and its Relation with the Dental Apical Inflammation Score (DAIS)“<\/p>\n

H. Jiang (in progress), „Needle Detection and Localization in Ultrasound Images based on Deep Learning“<\/p>\n

H. Jungreuthmayer (in progress), „Source-Detector Trajectory Optimization for Customized CBCT FOV Extension Using Simulated Annealing Algorithm“<\/p>\n

S. D.S. Kanhai (in progress), „Design of a Detailed Female Pelvis Model for Gynaecological Brachytherapy Applications“<\/p>\n

D. Leeb (in progress), „Intra-operative needle tracking for HDR of Cervical Tumor“<\/p>\n

B. Long (in progress), „AI Methods for Computer-Assisted Hernia Surgical Training“<\/p>\n

E. Lukacs (in progress), „Kinematic Data-Based Skill Assessment in Robot-Assisted Minimally Invasive Surgery“<\/p>\n

S. Nasser (in progress), „AI-Based Analysis of EKG Signal in Crucial Care Setting“<\/p>\n

L. Pool (in progress), „Design of a Patient-Tailored 3D-Printed HDR Brachytherapy Applicator for the Treatment of Cervical Cancer“<\/p>\n

O. Radcliff (in progress), „Intra-Operative High Frequency Ultrasound Imaging of Breast Cancer“<\/p>\n

L. de Rouw (in progress), „Design Requirements for Future Technology to Enhance Surgical Instrument Counting: An Observational Study at the Reinier de Graaf Gasthuis“<\/p>\n

R. Szabo (in progress), „Deep Learning Based Real-Time Decision Support System for Lung Ultrasound Evaluation“<\/p>\n

M. N. Toth (in progress), „Autonomous Phase Detection in Robot-Assisted Minimally Invasive Surgery“<\/p>\n

W. Wang (in progress), „Designing a Bone Fracture Apparatus for Surgical Training Applied on Human Cadaver“<\/p>\n

O. Wind (in progress), „Developing and Validating an Interoperability Mockup for ISO\/IEEE 11073-Compliant Devices in Smart Operating Rooms“<\/p>\n

J. Zong (in progress), „Computational Performance Analysis of the NousNav Neurosurgery Navigation System“<\/p>\n

D. P. Cernelev (2024), „Analysis of Electromagnetic Surgical Navigation“<\/p>\n

B. Huegen (2024), „The Design and Development of an Anthropomorphic Coronary Artery Network Phantom: To Assist in the Development and Validation of Novel Imaging-Related Technologies“<\/p>\n

A. J. Mommersteeg (2024), „Design of a Minimal Invasive Sentinel Lymph Node Biopsy Device: Actuating a Locally Expanding Adaptable Cutting Blade“<\/p>\n

M. F. Wempe (2024), „MINT-Minimally Invasive Tensiometry: A Device to Quantify Tension During Laparoscopic Herniorrhaphy“<\/p>\n

N. Kitner (2023), „Catheter Segmentation in Ultrasound for High Dose Rate Brachytherapy of the Prostate“<\/p>\n

A. Morton (2023), „Robot-Assisted Breast Cancer Surgery“<\/p>\n

A. Schonewille (2023), „Tracked 3D Ultrasound Navigated Abdominal Biopsy Procedure with Registered Tomographic Scans“<\/p>\n

M. Sandrini (2023), „Model Predictive Variable Impedance Control for Redundant Manipulators“<\/p>\n

D. Tognolo (2023), „Robotic Ultrasound System Based on Deep Reinforcement Learning“<\/p>\n

M. Asselin (2022), „A Flexible Framework for Semi-Automatic Inverse Planning of Abdominal Organ Tumor Ablation“<\/p>\n

C. Barr (2022), „Ultrasound Volume Reconstruction and Segmentation in Prostate Biopsy“<\/p>\n

L. Connolly (2022), „Robotic Breast Conserving Surgery“<\/p>\n

H. Jongeneel (2022), „Scheduling Cardiac Catheterization Laboratories with Monte Carlo Simulation“<\/p>\n

S. Koschitz (2022), „Development of a Functional Anatomical Model for Simulation of the Human Heartbeat“<\/p>\n

J. Keizer (2021), „Computer Vision in the Operation Room: Testing the Feasibility of a Computer Vision Algorithm for Instrument Detection in the Operation Room“<\/p>\n

L. Koopman (2021), „The Influence of Rotation on the Precision of Needle End-Point Position in Lateral Direction for Biopsy“<\/p>\n

R. Doczi (2021), „Realizing of a Complete Software Architecture for Eye Surgery Robots“<\/p>\n

M. Exenberger (2021), „Digitaler Workflow f\u00fcr Vollst\u00e4ndig Gef\u00fchrte Implantationen mit In-House Gefertigten Borschablonen (Pilotstudie)“<\/p>\n

I. van Heijningen (2021), „Development of a Novel Non-Invasive Expandable Knee Prothesis“<\/p>\n

R. Kolonics (2021), „Montage und Zentrierung Asph\u00e4rischer Linsen“<\/p>\n

E. van Koten (2021), „MINT: Minimally Invasive Tensiometry: A Novel Method to Assess Laparoscopic Herniorrhaphy“<\/p>\n

D. van der Molen (2021), „The Design of a Brain and Tumor Phantom: Focused on Mimicking the Stiffness of the Brain and Glioblastoma Multiforme Tumor Tissue“<\/p>\n

A. Santilli (2021), „Metabolomic Tissue Analysis“<\/p>\n

R. Boedhoe (2020), „Range of Motion Assessment during Total Hip Arthroplasty“<\/p>\n

H. Cherni (2020), „Cyber Security in Medical Robotics“<\/p>\n

F. Fessel (2020), „Pr\u00e4zision von 3D-gedruckten Zahnmodellen unter Anwendung Unterschiedlicher Fertigungstechnologien“<\/p>\n

G. Lajko (2020), „Endoscopic Image-Based Skill Assessment in Robot-Assisted Minimally Invasive Surgery“<\/p>\n

M. M. Nobel (2020), „The Design of a Manually Operated Compliant Mechanism Steerable Needle for High Dose-Rate Brachytherapy of the Prostate“<\/p>\n

E. Veldman (2020), „Design and Development of a Prostate Phantom Model to Mechanically Mimic Human Tissue“<\/p>\n

N. Zhang (2020), „Three-Axis Force-Sensing Hip Implant for Soft Tissue Tension Assessment during Total Hip Arthroplasty“<\/p>\n

E. Cakar (2019), „A Chaos-Based Signal Masking Application Using Liu System“<\/p>\n

L. Jaksa (2019), „Evaluation of a Ceramic 3D Printing Technology Considering Medical Applications“<\/p>\n

I. Nigicser (2019), „Rapidly Deployable Structures for Tissue Retraction“<\/p>\n

B. Sagmeister (2019), „Test System for a Dynamic Ligament Balancing Sensorplate“<\/p>\n

P. Suti (2019), „Hand Modeling and Image Segmentation with Real-time Algorithms“<\/p>\n

K. Takacs (2019), „Fundamentals of Robotic Laparoscopic Surgery“<\/p>\n

M. Bordeus (2018), „Berechnungsmodell der Bandsynapsen der Bipolarzellen in der Retina“<\/p>\n

B. Kocsis (2018), „Volumetric Visualization of Vessel Structure Gained from Infra or Thermal Images Coupled with (3D) CT, MRI“<\/p>\n

N. Loschko (2018), „Untersuchung \u00fcber die Wirkung Verschiedener Intraokularlinsen auf den Seheindruck unter Verwendung des IOL Simulators“<\/p>\n

V. S\u00e1ri (2018), „Objective Methods to Compare Hand Hygiene Assessment Tools“<\/p>\n

Cs. Urban (2018), „Virtual Ultrasound Trainer Development“<\/p>\n

K. Knopp (2017), „Microsurgical Performance under Stress: A NeuroTouch Simulator Study“<\/p>\n

Z. Pint\u00e9r (2017), „Intellectual Property Protection for Novel Medtech Devices“<\/p>\n

L. Oberleitener (2017), „Eine Pilotstudie zur Erforschung der Auswirkungen Verschiedener IOL Designs in Subjektiven 2D und 3D Szenarien“<\/p>\n

S. Ambardekar (2016), „Multifunctional Instrument for Intracranial Neurosurgery“<\/p>\n

Sz. Barcza (2016), „Automating Laparoscopic Camera Handling“<\/p>\n

R. Elek (2016), „Image-Based Camera Control for Surgical Robotic Interventions“<\/p>\n

S. Jordan (2016), „Surgical Robot Navigation and Control“<\/p>\n

E. K\u00e1m\u00e1n (2016), „Hand Model Fitting and Segmentation Validation“<\/p>\n

S. Seetharaman (2016), „New Software Interface for Robot-Assisted Needle Placement in Neurosurgery“<\/p>\n

S. Kumar (2015), „Implementation of an Integrated Document Management System at ACMIT and Croma Pharma“<\/p>\n

D. Nagy (2015), „An Automatic Method for Camera Positioning During Laparoscopic Surgery“<\/p>\n

R. V\u00f6r\u00f6s (2015), „Robotic Technology in Head and Neck Surgery“<\/p>\n

C. Nepel (2014), „\u00dcbersichtsarbeit zum Thema Posttraumatische und Antiinflammatorische Kryotherapie“<\/p>\n

H. Pock (2014), „Entwicklung eines Regelkreises auf Basis des Pelletier Effektes f\u00fcr Partielle K\u00f6rperk\u00fchlung“<\/p>\n

S. Bansaghi (2013), „Risk Perception on Hand Hygiene“<\/p>\n

V. Godri (2013), „Validating a Laparoscopic Trainer“<\/p>\n

T. Mayer (2013), „Evaluation of the Axial Shift of an Intraocular Lens Using a Capsular Bag Mechanical Model“<\/p>\n

N. Plank (2013), „Automatisierung eines Optischen Messaufbaus zur Charakterisierung von Intraokularlinsen“<\/p>\n

G. Fenyvesi (2012), „Susceptibility of Intra-operative Electromagentic Tracking Systems“<\/p>\n

A. Hahnekamp (2012), „Automatisierte Erkennung und Manipulation von Medizinischen Textilien“<\/p>\n

M. Nagy (2012), „Automation of Hand Washing Control“<\/p>\n

T. Neugebauer (2012), „Integration einer L\u00e4ngenmessvorrichtung in eine Chirurgische Bohrmaschine“<\/p>\n

V. Reisenbauer (2012), „Hochdruck Wasserstrahl Bearbeitung – Technische und Kaufm\u00e4nnische Bewertung“<\/p>\n

M. Fegerl (2011), „Modular Control System for Medical Robotics – Design and Implementation“<\/p>\n

M. Krenn (2011), „Usability Conform Scenario Configurator for a Therapeutic Robot System“<\/p>\n

A. Lehotsky (2011), „Developing a Hand Hygiene Control System“<\/p>\n

P. Steiger (2011), „Dynamische Analyse eines Segmentierten Antriebsstranges f\u00fcr Gekr\u00fcmmte Chirurgische Instrumente“<\/p>\n\t\t\t\t\t\t

Bachelor-Arbeiten<\/h4>\n\t\t\t

A. Graf (in progress), „Multi Data Integration for In-Vitro Personalized Reproductive Medicine“<\/p>\n

P. Koppensteiner (in progress), „Beitrag zum Design eines Robotersystems zur gezielten Prostata-Biopsie“<\/p>\n

B. Pohn (in progress), „AI and Imaging for In-Vitro Fertilization and Personalized Reproductive Medicine“<\/p>\n

J. Zakall (in progress), „Role of Radiomics in Personalized Reproductive Medicine“<\/p>\n

S. F\u00fcllenhals (2023), „Design und Bau einer Testumgebung f\u00fcr eine Roboter-Steuerung mit multi-modalem Feedback“<\/p>\n

D. Leeb (2023), „Ber\u00fchrungsfreie Patientenregistration mit einem 3D Kamerasystem“<\/p>\n

L. Plunger (2023), „Integrating Ontology, Surgical Process Modeling and Video Annotation for Workflow Analysis“<\/p>\n

O. Wind (2023), „Augmented Reality f\u00fcr die Unterst\u00fctzung von Navigierten Chirurgischen Prozessen“<\/p>\n

C. Reisinger (2021), „Nadelpositionierung zur Gewebeprobenentnahme mit einem Kollaborativen Roboter“<\/p>\n

B. Supper (2021), „Image-Based Automated Non-Technical Skill Assessment in Robotic Surgery“<\/p>\n

G. Benko (2020), „Development of Modular Vision System for Endoscopic Surgical Interventions“<\/p>\n

M. Markoczy (2019), „Reducing HAI with Technology“<\/p>\n

L. Gorbay-Nagy (2019), „Large Scale Objective Hand Hygiene Assessment“<\/p>\n

M. Racz (2019), „Image-Based Camera Control during Robotic Surgery“<\/p>\n

M. Rendes (2019), „Point Cloud Based Surface Estimation for Radiosurgery Treatment“<\/p>\n

G. T\u00f3th (2019), „Image-Based Camera Control for Robotic Surgery“<\/p>\n

R. Kolonics (2018), „Entwicklung eines 3D-Druckverfahrens f\u00fcr K\u00fcnstliche Gewebe aus Silikon“<\/p>\n

L. Jaksa (2017), „Force Feedback Unit Design for a Laparoscopic Surgical Simulator“<\/p>\n

M. Katana (2014), „Development of a Handheld Tool for Optimized Needle Insertion for Cervix Cancer Treatment“<\/p>\n

H. Pock (2014), „Entwicklung eines Regelkreises auf Basis des Peltier-Effektes f\u00fcr par Partielle K\u00f6rperk\u00fchlung“<\/p>\n

R. Nagl (2013), „Concentration-, Wavelength- and Temperature- dependent Determination of the Refractive Index of Saline Solutions“<\/p>\n

E. Rank (2013), „Construction of a Mechanical Eye Model for Evaluation of Physiological and Physical Optical Quality Criteria of Intraocular Lenses“<\/p>\n

P. Schattovich (2013), „Wireless Control of a Microrobot-prototype for Robotic Natural Orifice Transluminal Endoscopic Surgery“<\/p>\n

S. Schulz (2012), „Entwicklung eines Mikrocontrolleralgorithmus zur Charakterisierung von Gasen und deren Konzentration“<\/p>\n\t\t\t

Publikationen<\/h3>\n\t\t\t\t

Unsere wissenschaftlichen Arbeiten finden Sie auf Google Scholar<\/a>.<\/p>\n\t\t\t\n\t\t\t\t\t\t\tGoogle Scholar \n\t\t<\/a>\n\t\t\t

Projekte<\/h2>\n\t\t\t

Vertraulichkeitsvereinbarung<\/h3>\n\t\t\t\t

Viele Projekte unterliegen strengen Geheimhaltungsvereinbarungen. Wir bitten um Ihr Verst\u00e4ndnis, dass nur eine begrenzte Anzahl von Projekten im Projektbereich gezeigt werden kann.<\/p>\n\t\t\t

Einf\u00fchrung von Medizinprodukten mit relevantem ACMIT-Beitrag<\/h3>\n\t\n\t\"\"\n\t\u00a9Hinterramskogler\/ACMIT Gmbh\n

\n Anwendungsorientierte Modelle\n<\/h6>\n

ACMIT Gmbh<\/p>\n

Description<\/h6>\n