The Federal Ministry of Education and Research (BMBF) funds the project "Tangible reality - skilful interaction of user hands and fingers with real tools in mixed reality worlds (GreifbAR)" – a cooperation of the Augmented Vision group of the DFKI (Prof. Dr. Didier Stricker), the Department of Psychology and Human-Machine Interaction of the University of Passau (Prof. Dr. Susanne Mayr), the company NMY Mixed Reality Communication (Christoph Lenk), and the Experimental Surgery of Charité – Universitätsmedizin Berlin (Prof. Dr. Igor M. Sauer).

The goal of the GreifbAR project is to make extended reality (XR) worlds, including virtual (VR) and mixed reality (MR), tangible and graspable by allowing users to interact with real and virtual objects with their bare hands. Hand accuracy and dexterity is paramount for performing precise tasks in many fields, but the capture of hand-object interaction in current XR systems is woefully inadequate. Current systems rely on hand-held controllers or capture devices that are limited to hand gestures without contact with real objects. GreifbAR solves this limitation by proposing a sensing system that detects both the full hand grip including hand surface and object pose when users interact with real objects or tools. This sensing system will be integrated into a mixed reality training simulator.

Competent handling of instruments and suture material is the basis of every surgical activity. The main instruments used in surgery are in the hands of the surgical staff. Their work is characterised by the targeted use of a large number of instruments that have to be operated and controlled in different ways. Until now, surgical knotting techniques have been learned by means of personal instruction by experienced surgeons, blackboard images and video-based tutorials. A training and teaching concept based on the acquisition of finger movement does not yet exist in surgical education and training. Learning surgical account techniques through participant observation and direct instruction by experienced surgeons is cost-intensive and hardly scalable. This type of training is increasingly reaching its limits in daily clinical practice, which can be attributed in particular to the changed economic, social and regulatory conditions in surgical practice. Students and trainees as well as specialist staff in further training are therefore faced with the problem of applying and practising acquired theoretical knowledge in a practice-oriented manner. Text- and image-based media allow scalable theoretical knowledge acquisition independent of time and place. However, gestures and work steps can only be passively observed and subsequently imitated. Moreover, the learning success cannot be quantitatively measured and verified.

The aim of the Charité's sub-project is therefore to develop a surgical application scenario for Mixed/Augmented Reality (MR/AR) for the spatial guidance and verifying recording of complex fine motor finger movements for the creation of surgical knots, the practical implementation and technical testing of the developed concept within the framework of a demonstrator, and the evaluation of the usability of the system for use in a clinical context.

We have received the sad news that Professor Duška Dragun, Director of the Biomedical Innovation Academy (BIA) of the Berlin Institute of Health (BIH) and Head of the Charité BIH Clinician Scientist Program, succumbed to her long, severe, bravely endured illness on December 28, 2020 at the age of 51.
 
Her tireless efforts were devoted to her life's work: the Charité BIH Clinician Scientist Program. Ten years ago, she launched the first Clinician Scientist Program in Berlin and over the decade established and continuously expanded it as "best practice" for the German-speaking region. She has played a key role in developing and shaping the various programs for scientifically active physicians: from the Clinician Scientist Program, which enables aspiring specialists to spend up to 50 percent of their working time on research, to the Junior Clinician Scientist Program with 20 percent working time on research, which begins in the first year of specialist training, to the Advanced Clinician Scientist Program for specialists with postdoctoral qualifications. Two years ago, she successfully applied to the German Research Foundation (DFG) for the first and only Digital Clinician Scientist Program in Germany. This enables young physicians and scientists to conduct research and work in the field of digitalization in medicine and healthcare. Thus, within a few years, Duška Dragun made a significant contribution to building a new generation of young professionals for medicine – the impact of her programs will last for a long time, via promising individual careers as well as via the programmatic strengthening of a patient-oriented science.  
 
As a physician herself, Professor Duška Dragun has always been committed to research: As acting senior physician and deputy to the acting director of the Department of Nephrology and Intensive Care Medicine at the Charité Campus Virchow-Klinikum, as well as head of the nephrology research laboratory, she made highly regarded, internationally distinguished contributions to transplantation research with the goal of improving graft approach and long-term survival, preventing cardiovascular comorbidity, and thus improving the quality of life and life expectancy of transplanted patients.  She pursued her great goals with tremendous energy and passion, impressive perseverance and clear determination. She devoted her full attention to her employees, colleagues, and students, being equally attentive, understanding, and demanding.
 
The death of Duška Dragun is a great and painful loss. We will miss her greatly as director of the Charité BIH Clinician Scientist Program, as a physician, university professor and scientist. To us she was an inspiration, a mentor and an ever driving force.

Above all, however, we will greatly miss Duška as a friend.  

Dr. rer. medic. Moritz Queisner received his doctorate certificate today (magna cum laude)! This is in recognition of his work in the field of extended reality technology in visceral surgery. His thesis is entitled XR in surgery – spatial end embodied computing in digital surgery: technology, application, design.

CONGRATULATIONS !

Priv.-Doz. Dr. Felix Krenzien received the Ferdinand-Sauerbruch Prize 2020 for his project and publication „The ILLS Laparoscopic Liver Surgery Fellow Skills Curriculum“ published in Annals of Surgery (online ahead of print).

Congratulations!

Laparoscopy is becoming the standard approach in liver surgery. As the degree of difficulty varies greatly from core skills to advanced procedures, strategies for teaching young surgeons need to be reconsidered. We here aimed to design a skills curriculum for LLR. Using the nominal group technique, 22 substeps of LLR were identified by 61 hepatobiliary surgeons. The raters were asked to rate (1) the difficulty of substeps and (2) the minimum number of times that the substep must be performed for mastery of the technique. According to the frequency of defined substeps, being estimated on the basis of high volume center experiences (n = 222 LLR; 1/2017-12/2018), the center's training capacity and defined goals for a 2-year fellowship were calculated.
Ten surgical substeps (45%) are routinely performed and can thus be taught sufficiently at centers carrying out ≥50 LLR in 2 years. As the mobilization of the right liver lobe and the dissection of the hepatic artery or portal vein is performed in only 27% and 28% of all LLR, respectively, sufficient training can only be provided at centers with ≥100 LLRs in 2 years. Mastery of complex parenchymal dissection (19%) and hilar lymphadenectomy (8%) can only be achieved in center performing ≥200 LLR in 2 years.
The authors suggest a stepwise approach for training of hepatobiliary fellows in LLR. Based on the estimated complexity of the substeps and the size of the center, not every substep can be learned within 2 years.

Authors are Felix Krenzien, Wenzel Schöning, Philipp Brunnbauer, Christian Benzing, Robert Öllinger, Matthias Biebl, Marcus Bahra, Nathanael Raschzok, Daniel Cherqui, David Geller, Ho-Seong Han, Go Wakabayashi, Moritz Schmelzle, Johann Pratschke, and the study group of the International Laparoscopic Liver Society (ILLS).

„Der Simulierte Mensch“ ("The Simulated Human", Si-M) is a new research building which is currently under construction and is expected to be finished in 2023. The building site is directly adjacent to the Charité Campus Virchow-Klinikum of the Charité - Universitätsmedizin in Berlin-Wedding and is also the birthplace of biotechnology at the TU Berlin.

The initiators of Si-M are Roland Lauster (Head of the Department of Medical Biotechnology at TU Berlin) and Andreas Thiel (Head of the research group Regenerative Immunology and Aging at Charité – Universitätsmedizin Berlin). They applied for the research building in 2018 (GG §91b) and successfully defended it before the German Science Council.

In the building, scientists from both institutions will work together to simulate the functions of human cells and tissues with new technologies of 3D cultivation, multi-organ chips or 3D bioprinting. In contrast to already existing collaborative projects, the building will be used to practice the joint development of models "side by side" in the same laboratory environment. In this way, both the development of organ models and technological developments can be adapted and optimized at the same time.

More information via https://www.si-m.org .

The International Journal of Computer Assisted Radiology and Surgery accepted Christoph Rüger's paper on "Ultrasound in augmented reality: a mixed-methods evaluation of head-mounted displays in image-guided interventions" for publication.

Augmented reality (AR) and head-mounted displays (HMD) are current subjects of investigation in medical practice. A commonly proposed use-case of AR-HMDs is to display data in image-guided interventions. Although technical feasibility has been thoroughly shown, effects of AR-HMDs on interventions are not yet well researched, hampering clinical applicability. Therefore, the goal of this study is to better understand the benefits and limitations of this technology in ultrasound-guided interventions.
We used an AR-HMD system (based on Hololens, Microsoft Corp.) which overlays live ultrasound images spatially correctly at the location of the ultrasound transducer. We chose ultrasound-guided needle placements as a representative task for image-guided interventions. To examine the effects of the AR-HMD, we used mixed methods and conducted two studies in a lab setting: (1) in an experimental study, we asked participants to place needles into a training model and evaluated task duration and accuracy with the AR- HMD as compared to the standard procedure without visual overlay and (2) in a qualitative study, we analysed the user experience with AR-HMD using think-aloud protocols during ultrasound examinations and semi-structured interviews after the task.
Participants (n=20) placed needles more accurately (mean error of 7.4 mm vs. 4.9 mm, p=0.022) but not significantly faster (mean task duration of 74.4 s vs. 66.4 s, p=0.211) with the AR-HMD. All participants in the qualitative study (n=6) reported limitations of and unfamiliarity with the AR-HMD, yet all but one also clearly noted benefits and/or that they would like to test the technology in practice.
We present additional, though still preliminary, evidence that AR-HMDs provide benefits in image-guided procedures. Our data also contribute insights into potential causes underlying the benefits, such as improved spatial perception. Still, more comprehensive studies are needed to ascertain benefits for clinical applications and to clarify underlying mechanisms.

Authors are Christoph Rüger, Markus A. Feufel, Simon Moosburner, Christopher Özbek, Johann Pratschke, and Igor M. Sauer.

The Department of Surgery of the Charité (Director: Prof. Dr. Johann Pratschke) at the Charité Center 8 (CharitéCenter for Surgery) invites applications for the position of the Junior Professorship for Digital Surgery and interdisciplinary Technology Research (Salary Group: W1 BBesG-ÜfBE, non-tenured) with the reference number: Prof. 546/2020.

The initial appointment is for three years with the optional extension for another three years follow-ing successful evaluation. It is aimed to turn the Junior Professorship into a W2-Professorship (Salary Group: W2 BBesG-ÜfBE) after six years.The successful candidate has to fulfill the appointment requirements in accordance with § 102a of the Berlin Higher Education Act (Berliner Hochschulgesetz, Gem. § 102a BerlHG) and needs to credibly demonstrate through his/her previous scientific work that he/she is able to fulfill the expectations of the junior professorship.

One of the tasks of this Junior Professorship is the appropriate representation of the research area mentioned above. Within the framework of the Cluster of Excellence Matters of Activity – Image Space Material, he/she is expected to evaluate, accompany and advance the digital transformation in surgery and related disciplines as well as expand the repertoire of methods and initiate innovations. In cooperation with the research areas Cutting and Material Form Function of the Cluster of Excellence, new surgical cutting techniques are to be investigated and developed. It is planned to be linked to the currently being established institutions, The Simulated Human Being (Si-M) and the Berlin Simulation and Training Centre (BeST). In addition to the tasks mentioned, the following three fields of activity are to be covered:

Interdisciplinary Knowledge Transfer

• Implementation of new applications from areas such as deep learning, extended reality (mixed and virtual reality) or robotics in surgical practice requires an intensification of interdisciplinary cooperation
• Continuous exchange between industry and practice as well as with adjacent disciplines (e.g. Radiology)
• Integration of a growing number of applications and competencies from areas outside established medical technology, e.g.game design, computer science or human factor studies

Technology Assessment

• Sustainable implementation of digital technologies through opportunity and risk assessment
• Advising the Department of Surgery on investment decisions through appropriate risk and media competency

Innovation

• Identification of concrete application locations and practices of digital surgery within the clinic and experimental research (e.g. use of technologies in the context of biomedical research approaches to organ replacement as well as oncological models) for future Living Labs and to demonstrate these to the public
• Integration of users, research projects and start-ups also outside the Clinic

The successful candidate will be engaged in teaching activities of the medical education curriculum at Charité, supervise Master and Doctoral candidates, and participate in academic self-organization. In addition, the candidate should present concepts for a good supervision of doctoral students as well as for the integration of his/her research activities into the teaching of the Charité. Appointment requirements are governed by article 102a of the Berlin Higher Education Act (Berliner Hochschulgesetz:§ 102a BerlHG). Completed university degree in Natural Sciences, Humanities and/or Life Sciences or any other related field of Medicine or non-medicine is required. In addition, a Doctorate (Ph.D and/or M.D.) and significant post-doctoral experience are required. Basic medical knowledge is desired.

The Charité is an equal opportunity employer committed to excellence through diversity. As women are under-represented in academics, we explicitly encourage women to send in their application. Women will be given preference over equally qualified men (within the framework of the legal possibilities). We value diversity and therefore welcome all applications – regardless of gender, nationality, social background, religion or age. Equally qualified applicants with disabilities will be given preference.

Written applications according to the format specified on https://career.charite.de/am/calls/application_notes.pdf should be submittedby June 19th, 2020 under https://career.charite.de. For further questions on details, please contact Prof. Dr. Igor Maximilian Sauer.

Today, Simon Moosburner successfully defended his doctoral thesis entitled "Erweiterung der Spenderpopulation bei Lebertransplantation: Klinischer Bedarf und Entwicklung eines Kleintier-Lebermaschinenperfusionssystems (Expanding the donor pool for liver transplantation: clinical need and development of small animal liver perfusion system)" summa cum laude !

Congratulations!

The new book "Die Zukunft der Medizin: Disruptive Innovationen revolutionieren Medizin und Gesundheit" is available. Igor Maximilian Sauer, Moritz Queisner, Michael Pogorzhelskiy and Johann Pratschke contributed with the chapter "Operieren im digitalen Raum – Mixed Reality in der Chirurgie".
Editors are Erwin Böttinger and Jasper zu Putlitz.

Christoph Rüger successfully defended his thesis entitled "Ergonomische Untersuchungen zu Augmented Reality Head-Mounted Displays in der Ultraschallgeschützen Leberdiagnostik".

Congratulations!