Development and testing of a low cost simulation manikin for extracorporeal cardiopulmonary resuscitation (ECPR) using 3-dimensional printing

The effectiveness of a three-dimensional printed model for training novice healthcare professionals in central venous catheter insertion: A cross-sectional study in a critical care setting

BACKGROUND

We have previously used three-dimensional printing to develop a novel manikin for simulation training of central venous catheter insertion in critical care. The objective of this study was to evaluate the fidelity of the model by testing with novice and experienced operators.

METHODS

A convenience sample of intensivist physicians experienced in central venous catheter insertion and critical care nurses without prior central venous catheter training was assembled. Participants were offered a video educational clip and a one-on-one demonstration. All participants were then asked to insert a central venous catheter into the model. Outcomes included requests for assistance, success rate, time to insertion, and subjective feedback.

RESULTS

Thirteen intensivists and 14 nurses participated. Nurses were more likely to view the demonstration video prior to the procedure (13/14; 92.9% vs. 7/13; 53.9%; p = 0.033). Intensivists were more likely male (11/13; 84.6% vs. 3/14; 21.4%; p = 0.002) and tended to be older, with a higher proportion in the 35- to 44-year and 45- to 54-year age ranges than the nurses (92.3% vs. 71.4%; p = 0.426). Nurses requested more assistance and received more guidance but had similar overall success (100.0% vs 92.3%; p = 0.481). The median time taken for the procedure was 19 min and 59 s for nurses and 8 min and 14 s for intensivists (p = 0.004). All participants agreed that the model effectively prepared trainees for their first human central venous catheter insertion. Nurses also reported a significant increase in procedural confidence post simulation. Additionally, most participants agreed or strongly agreed that the model realistically simulated the femoral vein, an essential aspect of the central venous catheter insertion.

CONCLUSIONS

Nurses required additional assistance and took longer to complete the insertion, demonstrating preliminary evidence for the model's construct validity. Furthermore, the model was deemed a realistic training tool with successful insertion by nearly all participants.

Interprofessional Extracorporeal Membrane Oxygenation Cardiopulmonary Resuscitation Simulations Aimed at Decreasing Actual Cannulation Times: A Longitudinal Study

BACKGROUND

Since 2013, the cardiac intensive care unit (CICU) at Children's National has conducted annual extracorporeal membrane oxygenation cardiopulmonary resuscitation (ECPR) simulations that focus on team dynamics, room setup, and high-quality CPR. In 2019 and 2020, the simulations were expanded to include the surgical and extracorporeal membrane oxygenation (ECMO) teams in an effort to better understand and improve this process.

METHODS

During a 4-week period in 2019, 7 peripheral ECPR simulations were conducted, and through a 3-week period in 2020, 7 central ECPR simulations were conducted. Participants in each session included: 8 to 10 CICU nurses, 1 CICU attending, 1 to 2 ICU or cardiology fellows, 1 cardiovascular surgery fellow or attending, and 1 ECMO specialist. For each session, the scenario continued until the simulated patient was on full cardiopulmonary bypass. An ECMO trainer was used for peripheral simulations and a 3-dimensionally-printed heart was used for central cannulations. An ECMO checklist was used to objectively determine when the patient and room were fully prepared for surgical intervention, and simulated cannulation times were recorded for both groups. A retrospective chart review was conducted to compare actual cannulation times before and after the intervention period, and video was used to review the events and assist in dividing them into medical versus surgical phases. Control charts were used to trend the total ECPR times before and after the intervention period, and mean and P values were calculated for both ECPR times and for all other categorical data.

RESULTS

Mean peripheral ECPR times decreased significantly from 71.7 to 45.1 minutes ( P = 0.036) after the intervention period, and this was reflected by a centerline shift. Although we could not describe a similar decrease in central ECPR times because there were only 6 postintervention events, the times for each of these events were shorter than the historical mean of 37.8 minutes. There was a trend in improved survival, which did not meet significance both among patients undergoing peripheral ECPR (15.4% ± 10% to 43.8% ± 12.4%, P = 0.10) and central ECPR (36.4% ± 8.4% to 50% ± 25%, P = 0.60). The percentage of time dedicated to the medical phases of the actual versus simulated procedures was very consistent among both peripheral (33.0% vs. 31.9%) and central (39.6% vs. 39.8%) cannulations.

CONCLUSIONS

We observed a significant decrease in peripheral cannulation times at our institution after conducting interprofessional ECPR simulations taken to the establishment of full cardiopulmonary bypass. The use of an ECMO trainer and a 3-dimensionally-printed heart allowed for both the medical and surgical phases of the procedure to be studied in detail, providing opportunities to streamline and improve this complex process. Larger multisite studies will be needed in the future to assess the effect of efforts like these on patient survival.

Application of Advanced Technologies-Nanotechnology, Genomics Technology, and 3D Printing Technology-In Precision Anesthesia: A Comprehensive Narrative Review

There has been increasing interest and rapid developments in precision medicine, which is a new medical concept and model based on individualized medicine with the joint application of genomics, bioinformatics engineering, and big data science. By applying numerous emerging medical frontier technologies, precision medicine could allow individualized and precise treatment for specific diseases and patients. This article reviews the application and progress of advanced technologies in the anesthesiology field, in which nanotechnology and genomics can provide more personalized anesthesia protocols, while 3D printing can yield more patient-friendly anesthesia supplies and technical training materials to improve the accuracy and efficiency of decision-making in anesthesiology. The objective of this manuscript is to analyze the recent scientific evidence on the application of nanotechnology in anesthesiology. It specifically focuses on nanomedicine, precision medicine, and clinical anesthesia. In addition, it also includes genomics and 3D printing. By studying the current research and advancements in these advanced technologies, this review aims to provide a deeper understanding of the potential impact of these advanced technologies on improving anesthesia techniques, personalized pain management, and advancing precision medicine in the field of anesthesia.

Experimental evaluation of impact-resistant gloves using surrogate hands

Injuries to the hand and fingers with varying degrees of severity are widespread in industries such as mining and oil and gas production. This study presents the results of tests carried out to measure the impact performance for commonly used impact-resistant gloves (metacarpal gloves). Sets of surrogate hands made out of a 3D-printed skeletal structure and soft tissues represented by synthetic gel were manufactured and subjected to controlled impact tests. The calibration and validation of the surrogates were based on impact response data reported previously for cadaveric specimens. Calibrated surrogate hand specimens were tested to assess the impact protection of typical metacarpal gloves. Each type of metacarpal glove provided different levels of protection measured by the decrease in the peak impact reaction force and the fractures detected after the impacts. Results indicated that surrogate specimens suffered fractures in 77% and 33% of the impacts for unprotected and protected hands, respectively.

Extracorporeal cardiopulmonary resuscitation in adults and children: A review of literature, published guidelines and pediatric single-center program building experience

Extracorporeal cardiopulmonary resuscitation (ECPR) is an adjunct supportive therapy to conventional cardiopulmonary resuscitation (CCPR) employing veno-arterial extracorporeal membrane oxygenation (VA-ECMO) in the setting of refractory cardiac arrest. Its use has seen a significant increase in the past decade, providing hope for good functional recovery to patients with cardiac arrest refractory to conventional resuscitation maneuvers. This review paper aims to summarize key findings from the ECPR literature available to date as well as the recommendations for ECPR set forth by leading national and international resuscitation societies. Additionally, we describe the successful pediatric ECPR program at Texas Children's Hospital, highlighting the logistical, technical and educational features of the program.

Mechanical Characterization of Synthetic Gels for Creation of Surrogate Hands Subjected to Low-Velocity Impacts

The development of human body simulators that can be used as surrogates for testing protective devices and measures requires selecting synthetic materials with mechanical properties closely representative of the human tissues under consideration. For impact tests, gelatinous materials are often used to represent the soft tissues as a whole without distinguishing layers such as skin, fat, or muscles. This research focuses on the mechanical characterization of medical-grade synthetic gels that can be implemented to represent the soft tissues of the hand. Six grades of commercially available gels are selected for quasi-static hardness and firmness tests as well as for controlled low-velocity impact tests, which are not routinely conducted by gel manufacturers and require additional considerations such as energy level and specimen sizes relevant to the specific application. Specimens subject to impacts represent the hand thicknesses at the fingers, knuckles, and mid-metacarpal regions. Two impact test configurations are considered: one with the gel specimens including a solid insert representing a bone and one without this insert. The impact behavior of the candidate gels is evaluated by the coefficient of restitution, the energy loss percentage, and the peak reaction force at the time of impact. The resulting values are compared with similar indicators reported for experiments with cadaveric hands. Relatively softer gels, characterized by Shore OOO hardness in the range of 32.6 ± 0.9 to 34.4 ± 2.0, closely matched the impact behavior of cadaveric specimens. These results show that softer gels would be the most suitable gels to represent soft tissues in the creation of surrogate hands that can be used for extensive impact testing, thus, minimizing the need for cadaveric specimens.

Fabrication and Characterization of Tissue-Mimicking Phantoms for Ultrasound-Guided Cannulation Training

Tissue-mimicking materials (TMMs) have been investigated and used for decades as imaging phantoms in various medical applications. They are designed and fabricated to replicate certain biological tissue characteristics, a process often dictated by the target application. Moreover, TMMs have been utilized in some medical procedural training requiring the use of imaging modalities. One potential application for TMMs is ultrasound-guided cannulation training. Cannulation is a procedure that requires a level of dexterity to gain vascular access using ultrasound guidance while avoiding complications like vessel laceration and bleeding. However, an ideal phantom for this application is yet to be developed. This work investigates the development and characterization of high-fidelity phantoms for cannulation training. The mechanical (shore hardness, elastic modulus, and needle-interaction forces) and acoustic (B-mode ultrasound scans) properties of candidate materials were quantitatively compared with biological tissue. The evaluated materials included ballistic gel, plasticized polyvinyl chloride (PVC), silicone, gelatin, agar, and polyvinyl alcohol (PVA)- cryogel. Mechanical testing demonstrated that each material could replicate the Shore hardness and elasticity characteristics of different biological tissues (skin, fat, and muscle), with PVA and PVC showing tunability by varying composition or fabrication processes. Shore hardness (OO-range) for PVA ranged between 6.3 ± 1.0 to 59.3 ± 2.6 and PVC from 4.8 ± 0.7 to 14.6 ± 0.8. Ultrasound scans of PVA were the closest to human scans, both qualitatively (based on experts' opinion) and quantitatively (based on pixel intensity measurements). Modified mixtures of PVA are found to best serve as high-fidelity cannulation phantoms. Alternatively, PVC can be used to avoid troublesome fabrication processes of PVA.

The Role of 3D Printing in Planning Complex Medical Procedures and Training of Medical Professionals-Cross-Sectional Multispecialty Review

Medicine is a rapidly-evolving discipline, with progress picking up pace with each passing decade. This constant evolution results in the introduction of new tools and methods, which in turn occasionally leads to paradigm shifts across the affected medical fields. The following review attempts to showcase how 3D printing has begun to reshape and improve processes across various medical specialties and where it has the potential to make a significant impact. The current state-of-the-art, as well as real-life clinical applications of 3D printing, are reflected in the perspectives of specialists practicing in the selected disciplines, with a focus on pre-procedural planning, simulation (rehearsal) of non-routine procedures, and on medical education and training. A review of the latest multidisciplinary literature on the subject offers a general summary of the advances enabled by 3D printing. Numerous advantages and applications were found, such as gaining better insight into patient-specific anatomy, better pre-operative planning, mock simulated surgeries, simulation-based training and education, development of surgical guides and other tools, patient-specific implants, bioprinted organs or structures, and counseling of patients. It was evident that pre-procedural planning and rehearsing of unusual or difficult procedures and training of medical professionals in these procedures are extremely useful and transformative.

A Review of Human Circulatory System Simulation: Bridging the Gap between Engineering and Medicine

(1) Background: Simulation-based training (SBT) is the practice of using hands-on training to immerse learners in a risk-free and high-fidelity environment. SBT is used in various fields due to its risk-free benefits from a safety and an economic perspective. In addition, SBT provides immersive training unmatched by traditional teaching the interactive visualization needed in particular scenarios. Medical SBT is a prevalent practice as it allows for a platform for learners to learn in a risk-free and cost-effective environment, especially in critical care, as mistakes could easily cause fatalities. An essential category of care is human circulatory system care (HCSC), which includes essential-to-simulate complications such as cardiac arrest. (2) Methods: In this paper, a deeper look onto existing human circulatory system medical SBT is presented to assess and highlight the important features that should be present with a focus on extracorporeal membrane oxygenation cannulation (ECMO) simulators and cardiac catheterization. (3) Results: A list of features is also suggested for an ideal simulator to bridge the gap between medical studies and simulator engineering, followed by a case study of an ECMO SBT system design. (4) Conclusions: a collection and discussion of existing work for HCSC SBT are portrayed as a guide for researchers and practitioners to compare existing SBT and recreating them effectively.

Applications of 3D printing in critical care medicine: A scoping review

Although a wide range of medical applications for three-dimensional printing technology have been recognised, little has been described about its utility in critical care medicine. The aim of this review was to identify three-dimensional printing applications related to critical care practice. A scoping review of the literature was conducted via a systematic search of three databases. A priori specified themes included airway management, procedural support, and simulation and medical education. The search identified 1544 articles, of which 65 were included. Ranging across many applications, most were published since 2016 in non - critical care discipline-specific journals. Most studies related to the application of three-dimensional printed models of simulation and reported good fidelity; however, several studies reported that the models poorly represented human tissue characteristics. Randomised controlled trials found some models were equivalent to commercial airway-related skills trainers. Several studies relating to the use of three-dimensional printing model simulations for spinal and neuraxial procedures reported a high degree of realism, including ultrasonography applications three-dimensional printing technologies. This scoping review identified several novel applications for three-dimensional printing in critical care medicine. Three-dimensional printing technologies have been under-utilised in critical care and provide opportunities for future research.