Ergonomics in Laparoscopic Surgery

Despite the many advantages for patients, laparoscopic surgery entails certain ergonomic inconveniences for surgeons, which may result in decreasing the surgeons’ performance and musculoskeletal disorders. In this chapter, the current status of ergonomics in laparoscopy, laparoendoscopic single‐site surgery (LESS), and robot‐assisted surgery will be reviewed. Ergonomic guidelines for laparoscopic surgical practice and methods for ergonomic assessment in surgery will be described. Results will be based on the scientific literature and our experience. Results showed that the surgeon\u27s posture during laparoscopic surgery is mainly affected by the static body postures, the height of the operating table, the design of the surgical instruments, the position of the main screen, and the use of foot pedals. Ergonomics during the laparoscopic surgical practice is related to the level of experience. Better ergonomic conditions entail an improvement in task performance. Laparoscopic instruments with axial handle lead to a more ergonomic posture for the wrist compared to a ring handle. LESS is physically more demanding than conventional and hybrid approaches, requiring greater level of muscular activity in the back and arm muscles, but better wrist position compared with traditional laparoscopy. Physical and cognitive ergonomics with robotic assistance were significantly less challenging when compared to conventional laparoscopic surgery

Handheld Devices for Laparoscopic Surgery

Despite the well-known benefits of minimally invasive surgery (MIS) to the patients, this surgical technique implies some technical challenges for surgeons. These technical limitations are increased with the introduction of laparoendoscopic single-site (LESS) surgery. In order to overcome some of these technical difficulties, new handheld devices have been developed, providing improved functionalities along with precision-driven and articulating instrument tips. In this chapter, we will review the current status of handheld devices for laparoscopy and LESS surgery. Devices that provide additional and innovative functionalities in comparison with conventional surgical instruments will be considered. Results will be based on studies published in the scientific literature and our experience. These surgical devices will be organized into two main groups, mechanical devices and robotic-driven devices. In general, these instruments intend to simulate the dexterity of movements of a human wrist. Mechanical devices are cheaper and easier to develop, so most of the available handheld instruments fall into this category. The majority of the robotic-driven devices are needle holders with an articulating tip, controlled by an interface implemented on the instrument handle. In general, these handheld devices claim to offer an enhancement of dexterity, precision, and ergonomics

Video-based assistance system for training in minimally invasive surgery

In this paper, the development of an assisting system for laparoscopic surgical training is presented. With this system, we expect to facilitate the training process at the first stages of training in laparoscopic surgery and to contribute to an objective evaluation of surgical skills. To achieve this, we propose the insertion of multimedia contents and outlines of work adapted to the level of experience of trainees and the detection of the movements of the laparoscopic instrument into the monitored image. A module to track the instrument is implemented focusing on the tip of the laparoscopic tool. This tracking method does not need the presence of artificial marks or special colours to distinguish the instruments. Similarly, the system has another method based on visual tracking to localize support multimedia content in a stable position of the field of vision. Therefore, this position of the support content is adapted to the movements of the camera or the working area. Experimental results are presented to show the feasibility of the proposed system for assisting in laparoscopic surgical training

Methods and Tools for Objective Assessment of Psychomotor Skills in Laparoscopic Surgery

Training and assessment paradigms for laparoscopic surgical skills are evolving from traditional mentor–trainee tutorship towards structured, more objective and safer programs. Accreditation of surgeons requires reaching a consensus on metrics and tasks used to assess surgeons’ psychomotor skills. Ongoing development of tracking systems and software solutions has allowed for the expansion of novel training and assessment means in laparoscopy. The current challenge is to adapt and include these systems within training programs, and to exploit their possibilities for evaluation purposes. This paper describes the state of the art in research on measuring and assessing psychomotor laparoscopic skills. It gives an overview on tracking systems as well as on metrics and advanced statistical and machine learning techniques employed for evaluation purposes. The later ones have a potential to be used as an aid in deciding on the surgical competence level, which is an important aspect when accreditation of the surgeons in particular, and patient safety in general, are considered. The prospective of these methods and tools make them complementary means for surgical assessment of motor skills, especially in the early stages of training. Successful examples such as the Fundamentals of Laparoscopic Surgery should help drive a paradigm change to structured curricula based on objective parameters. These may improve the accreditation of new surgeons, as well as optimize their already overloaded training schedules

Laparoscopic Pancreas Surgery: Image Guidance Solutions

Pancreatic ductal adenocarcinoma (PDA) is the fourth leading cause of cancer-related deaths. Surgery is the only viable treatment, but irradical resection rates are still high. Laparoscopic pancreatic surgery has some technical limitations for surgeons and tumor identification may be challenging. Image-guided techniques provide intraoperative margin assessment and visualization methods, which may be advantageous in guiding the surgeon to achieve curative resections and therefore improve the surgical outcomes. In this chapter, current available laparoscopic surgical approaches and image-guided techniques for pancreatic surgery are reviewed. Surgical outcomes of pancreaticoduodenectomy and distal pancreatectomy performed by laparoscopy, laparoendoscopic single-site surgery (LESS), and robotic surgery are included and analyzed. Besides, image-guided techniques such as intraoperative near-infrared fluorescence imaging and surgical navigation are presented as emerging techniques. Results show that minimally invasive procedures reported a reduction of blood loss, reduced length of hospital stay, and positive resection margins, as well as an improvement in spleen-preserving rates, when compared to open surgery. Studies reported that fluorescence-guided pancreatic surgery might be beneficial in cases where the pancreatic anatomy is difficult to identify. The first approach of a surgical navigation system for guidance during pancreatic resection procedures is presented, combining preoperative images (CT and MRI) with intraoperative laparoscopic ultrasound imaging

Wearable Technology for the Validation of Surgical Systems and Surgical Assistance

Advances in sensors, internet of things and artificial intelligence are allowing wearable technology to constantly evolve, making it possible to have increasingly compact and versatile devices with clinically relevant and promising functionalities in the field of surgery. In this sense, wearable technology has been used in various fields of clinical and preclinical application such as the evaluation of the surgeon's ergonomic conditions, the interaction with the patient or the quality of the intervention, as well as surgical planning and assistance during the intervention. In this work we will present different types of wearable technologies for their application in the validation of surgical devices in minimally invasive surgery, and their application in assisting the surgical process. Within these technologies we will show electrodermal activity and electrocardiography devices to monitor the surgeon’s physiological state, and electromyography and motion analysis systems to study his/her ergonomics during the surgical practice. Apart from these systems, the introduction of extended reality technology (virtual, augmented, and mixed reality) has fostered the emergence of new immersive and interactive tools to assist in the planning of complex surgical procedures, surgical support and telementoring. As we can see, the application of wearable technology has a high impact on the validation of surgical systems in minimally invasive surgery, including laparoscopic surgery, microsurgery, and surgical robotics, as well as in the assistance of the surgical process, with the consequent benefit in the quality of patient care

Advanced Ergonomics in Laparoscopic Surgery

Applied ergonomics is very important in minimally invasive surgery (MIS), especially with the introduction of robotized techniques that have changed the surgeons’ work conditions. However, the main aim remains the engineering to enable the compatibility of fulfillment of surgeons’ tasks in a physical, logical, and organizational environment with security, comfort, and efficiency. Ergonomics contribution is oriented both to design and redesign utilized material and to work organization. Epidemiological studies have shown the appearance of musculoskeletal pathologies in surgeons performing MIS; therefore, it is relevant to identify the intensity, frequency, and duration of risk factors (posture, repeatability, level of effort, touch pressure, and vibration if relevant) associated with this profession. A further relevant consequence of the effort applied during MIS is local muscle fatigue (LMF), an important factor to consider in musculoskeletal pathologies. The aim of this chapter is to present different methodological approaches by employing most advanced technologies to define the most appropriate posture that surgeons should adopt during MIS to decrease LMF apparition risk level and at the same time to increase capacity to variate the posture without reducing the precision task performance

Extracción y recuperación de contenidos basado en vídeo en cirugía de mínima invasión

La introducción de las cirugías de mínima invasión en rutina clínica ha provocado la incorporación de los sistemas de vídeo dentro del quirófano. Así, estas técnicas proporcionan al cirujano imágenes que antes solo podían ser vistas mediante cirugía abierta. Los vídeos obtenidos en las intervenciones son almacenados en repositorios. El uso posterior de estos vídeos se ve limitado generalmente a su reproducción, debido a las dificultades de clasificación y gestión. La información que contienen estos repositorios puede ser explotada, reutilizando el conocimiento obtenido en cirugías similares. En este artículo de investigación se presenta el diseño de un módulo de gestión de conocimiento (MGC) para un repositorio de vídeos de cirugía de mínima invasión (CMI). El objetivo del módulo es gestionar y reutilizar la información contenida en el repositorio de vídeos laparoscópicos, para que puedan ser utilizadas con las experiencias previas en entornos de formación de nuevos cirujanos. Para este fin, se han implementado técnicas de recuperación de imagen y vídeo basadas en sus contenidos visuales (CBIR y CBVR). El MGC permite la recuperación de imágenes/vídeos, proporcionando información sobre la tarea que se está realizando en la escena quirúrgica. Los resultados obtenidos en este trabajo muestran la posibilidad de recuperar vídeos de CMI, a partir del instrumental presente en la escena quirúrgica

Procedimiento automático para el calibrado de cámaras: Estudio comparativo de la distorsión en diferentes combinaciones de cámaras y ópticas laparoscópicas

En este trabajo se propone un método de calibración automático para el cálculo y corrección de la distorsión en imágenes producida por las lentes de los sistemas de captura. Este procedimiento ha sido empleado como herramienta para analizar la distorsión provocada por diversos sistemas de cámara y óptica laparoscópica, de modo que podamos determinar el sistema que proporciona una imagen más fiable al cirujano