A 5G-powered robot-assisted teleultrasound diagnostic system in an intensive care unit

Telemedicine makes use of modern communication, electronic and computer technology to facilitate remote collection, storage, processing, transmission and querying of various medical information, in order to expand the scope of patient access to medical services by crossing geographical barriers, and is a discipline that provides clinical support for patients, thereby improving patient health [1]. Many studies have shown that remote consultations help to avoid the unnecessary long-distance transport of patients, which saves time and costs for the patient, and improves the quality of medical services [2‐4]. The application of telemedicine in the intensive care unit can be traced back to the telemedicine consulting service implemented by Grundy et al. [5] in the 1980s. Studies have shown that when telemedicine technology is used in intensive care units, it can have a significant and positive impact on the prognosis of critically ill patients [6‐8].

Ultrasound, an examination method that systematically shows the structure of organs, and which incorporates Doppler technology to show blood flow and measurement indicators, has become the core technology of critical care diagnosis and treatment and is widely used in intensive care wards [9, 10]. Point-of-care ultrasound (POCUS) is a non-invasive, non-toxic, and portable tool which has important clinical significance for evaluating critically ill patients, quickly identifying life-threatening diagnoses, and guiding invasive surgery in the intensive care unit [11]. However, traditional ultrasound requires the doctor/sonographer to carry equipment and wear isolation gowns when entering the intensive care and isolation ward for examination, which not only prolongs the consultation time, but also undoubtedly increases the potential risk of infection for medical staffs. The implementation of telemedicine provides a unique solution for critical care ultrasound examination.

In recent years, the development of computer networks, multimedia and communication technology has promoted the development of robot-assisted teleultrasound technology, and there has been an accumulation of abundant experience related to abdominal, heart, pelvic, obstetric, vascular and thyroid examinations [12]. The robot-assisted teleultrasound diagnostic system not only allows for dynamic observation with no radiation damage, but also reduces the risk of infection of medical staffs [13]. However, there are currently no feasibility studies on the application of a robot-assisted teleultrasound diagnostic system in intensive care units. This study explores the feasibility of implementing a 5G-powered robot-assisted teleultrasound diagnostic system in an intensive care unit.

A total of 33 robot-assisted teleultrasound examinations were performed in this study. Among them, one patient was excluded due to severe intestinal gas interference and poor image quality. The remaining 32 patients underwent ultrasound examinations of the liver, gallbladder, pancreas, spleen, kidney as well as examinations for pleural effusion and abdominal effusion in accordance with the preliminary plan. Among them, 20 were male patients; 12 were female patients. The average age of the patients was 61 ± 20 years old, among which the oldest was 94 years old and the youngest was 13 years old. The longest time taken for remote ultrasound diagnosis was 37 min, the shortest was 9 min, and the average consultation time was 17 ± 7 min.

Of the 32 patients in this study, 26 had positive results and 6 had negative results. There were 5 cases with inconsistent diagnosis between the two parties (Table 1). Among them, there were 3 cases where there was a positive bedside ultrasound diagnosis but a missed diagnosis by robot-assisted teleultrasound, namely: 2 cases of liver cysts and 1 case of gallbladder polyp; and 2 cases with positive diagnosis via robot-assisted teleultrasound but missed diagnosis at the bedside, namely: 1 case of liver cyst, and 1 case of intrahepatic calcification. A total of 17 types of diseases were found in the positive results, of which the most frequently diagnosed were as follows: thick and rough gallbladder wall, 14 cases; gallbladder deposits, 12 cases; pleural effusion, 9 cases; abdominal effusion, 8 cases; liver cysts, 8 cases.

The Chi-square test and the Kappa consistency test were used to perform statistical analysis on all data to evaluate the diagnostic differences and consistency between robot-assisted teleultrasound examination and bedside ultrasound examination (Table 2). In general, the McNemar value associated with the two inspection methods was close to 1, the Kappa value was 0.600, and the p value was < 0.001. The overall diagnosis results were basically the same, and there was no significant difference in the level of diagnosis. In addition, there was no significant difference in the diagnosis of 14 disease types using the two examination methods, and the level of consistency was high. The diagnosis of liver cysts was inconsistent in 3 cases. The McNemar value was close to 1, the Kappa value was 0.711, and the p value was less than 0.05, indicating that the diagnostic results of the two examination methods were essentially the same, and there was no difference in the level of diagnosis. Intrahepatic calcification and gallbladder polyps were diagnosed in 1 case with each examination, the McNemar value was close to 1, the Kappa value was 0.652, and the p value was less than 0.001, indicating that the diagnostic results associated with the two examination methods were basically the same, and there was no significant difference in the diagnosis level.

On the basis of the internationally prescribed 5-level absolute evaluation scale, two transmission experts who were not present used a subjective quality scoring method to score ultrasound images that had been transmitted with the use of the 5G network. Among them, the number of cases with a score of 5 was greater than 70%. The average score of image quality provided by the two experts was greater than 4 points, and the total average score was 4.73 points, which represents a high-quality image (Table 3).

After the robot-assisted teleultrasound examination, the clinician in the intensive care unit evaluated the patient’s vital signs. All the vital signs of the patients showed no significant changes, and no complications related to the examination were found, which preliminarily demonstrates the safety of teleultrasound examination with the assistance of a robotic arm.

According to a report published by Subramanian et al. [14] in <Critical Care Medicine> in 2020, two-thirds of remote intensive care centers use remote radiology to assist in the management of patients; however, they did not specifically mention the role of teleultrasound in the management of critically ill patients [15]. In fact, from a practical perspective, for critically ill patients on an isolation ward, CT examination is not only inconvenient because the patient has to be transported to the imaging area, but it also increases patient exposure to radiation, which is not conducive to repeated dynamic observations; furthermore, the difficulty associated with CT scanner disinfection increases the possibility of cross infection [13]. Teleultrasound is a kind of telemedicine science that transmits ultrasound images of difficult cases in remote areas to higher-level hospitals through the network, whereby consultation experts can provide a diagnosis as well as analysis for decision-making. It provides effective solutions to the problems arising from limited medical resources, a lack of local expertise, and situations involving a high risk of infection [16]. In this study, through the application of 5G network technology, 32 ultrasound examinations were completed with the use of a robot-assisted teleultrasound diagnostic system. Whether considered from the perspective of network transmission speed, image quality, or consistency with bedside ultrasound results, the findings in this study demonstrated that robot-assisted teleultrasound diagnosis has a relatively high level of feasibility in the intensive care unit and provides a novel solution for the application of ultrasound in the intensive care unit.

It has been shown that the sensitivity, specificity, and accuracy of ultrasound in the diagnosis of pleural effusion are about 84%, 100%, and 94%, respectively, and the results are equivalent or superior to routine chest X-ray examinations in a series of surgical ICU patients [17]. Ultrasound is similarly applicable to the diagnosis of abdominal effusion. We used robot-assisted teleultrasound to diagnose pleural effusion and abdominal effusion, and 9 cases with pleural effusion and 8 cases with abdominal effusion were identified. The results of teleultrasound diagnosis were 100% consistent with the results of bedside ultrasound examination results, with no differences observed. However, since most patients in the intensive care unit could only remain in the supine position and could not stand, lie on their side or get up to facilitate the localization of pleural effusion during examinations, we only performed a qualitative diagnosis in this study, and did not perform localized diagnosis. This can be a direction for future development with regards to the application of robot-assisted teleultrasound in intensive care units.

For critically ill patients in the intensive care unit, acalculous cholecystitis is a very common condition in critical care medicine. The atypicality of clinical symptoms increases the difficulty of assessment, but ultrasound can provide additional information to enable a diagnosis to be made [18]. Ultrasound manifestations of acalculous cholecystitis are as follows: gallbladder volume enlargement (short axis diameter > 40 mm), wall thickness (> 3 mm), or "bilateral signs", with flocculent deposits in the gallbladder. Combined with clinical laboratory indicators, the diagnosis can be made. In this study, 2 patients had the above-mentioned ultrasound findings, and there were no ultrasound signs of stones or polyps. It is therefore recommended that intensive care physicians combine clinical indicators for further diagnosis. In these two patients, the results of teleultrasound diagnosis were consistent with those of bedside ultrasound. The diagnostic results were consistent, and there was no significant difference in the level of diagnosis. In the remaining examinations, two cases of hepatic cysts and one case of gallbladder polyp were missed in teleultrasound diagnosis, while one case of liver cyst and one case of intrahepatic calcification were missed by bedside ultrasound. In general, the Kappa value of the two examination methods was 0.600, and the p value was < 0.001, indicating that the overall diagnostic results associated with the two methods were basically the same, and there was no significant difference in the diagnosis level.

In the early development of robot-assisted teleultrasound, the quality of ultrasound images was limited by network bandwidth, and the image display was not very clear [19, 20]. With advancements in network technology, however, the image quality transmitted by the robot-assisted teleultrasound diagnostic system has improved. It has been shown that the image quality associated with this method is comparable to that of traditional ultrasound [21, 22]. Compared with 4G network technology, the transmission rate of the latest 5G network communication technology is 20 times better, the mobile speed is 1.5 times better, and the delay is reduced by a factor of 10. It has high bandwidth, low delay, and wide connectivity, and can fully support the transmission of multi-channel high-definition video, accurate real-time transmission of ultrasound images, and at the same time enable the networking of a large amount of medical equipment inside and outside the hospital. The ultrasound image obtained by the 5G-powered robot-assisted teleultrasound diagnostic system was evaluated using an internationally standardized subjective quality scoring method. The average score with regards to image quality was 4.73 points, which represents a high-quality image, surpassing the limitations of previous networks regarding ultrasound image transmission, thereby meeting the requirements of teleultrasound diagnosis.

A 2017 study by Scott J. Adams et al. demonstrated that it is feasible to use a robot-assisted teleultrasound system for adult abdominal examinations. However, their system had technical limitations. The sonographer could not control the pressure and movement of the probe, resulting in the need for an on-site assistant on the patient side to position the robotic arm and apply pressure on the patient's abdomen [23]. Our robot-assisted teleultrasound diagnostic system could be started by remote connection at the press of a button, thus directly initiating the mechanical arm, which moves flexibly along the contours of the human body with appropriate pressure. The mechanical arm had a maximum speed and pressure limit, and the force of the mechanical arm could be set by the doctor in the range of 3–40 N. In our study, the teleultrasound control panel could be used to achieve remote adjustment of the parameters of the patient's ultrasound, including frequency, gain, depth, parameter measurement, etc. In addition, this system had dual protection devices and a function called "stop if excessive force + emergency stop button", which helped to fully ensure patient safety. In the 2019 novel coronavirus disease (COVID-19) crisis, high-resolution CT (HRCT) imaging was widely used in the diagnosis of COVID-19 due to its high spatial resolution. However, potential hazards still remain with regards to this procedure [12, 13]. At present, increasing evidence shows that ultrasound plays an important role in the diagnosis and treatment of COVID-19 patients, and provides an important basis for formulating treatment strategies [24, 25]. A number of studies have used 5G-powered robot-assisted teleultrasound diagnostic systems to achieve effective ultrasound assessment for evaluating the cardiopulmonary function of COVID-19 patients. Preliminary results show that the protocol is feasible [12, 13, 26, 27]. But the sample sizes in these studies were small and the results lacked statistical significance. This study was based on a 5G-powered robot-assisted teleultrasound diagnostic system, and its preliminary application in the intensive care unit was investigated, which demonstrated its feasibility, providing a better foundation for the medical management of patients in intensive care units during a possible future epidemic.

This research preliminarily demonstrates the feasibility of applying a 5G-powered robot-assisted teleultrasound diagnostic system in an intensive care unit. But there are limitations. First of all, although the mechanical arm can achieve movement with six degrees of freedom, it still has restrictions on the side. It is necessary to manually move the position of the machine away from the bed to achieve the desired direction. Secondly, the system currently lacks a cardiac probe and cannot perform scans of the heart. In addition, the operating doctors in this study were all senior ultrasound experts, and we did not investigate whether less experienced ultrasound doctors could also carry out the examination easily. Finally, robotic tele-operation is indeed a certain challenge for remote experts in terms of 3D space perception. Doctors need to repeatedly practice and familiarize themselves with the operation process, so as to realize the "human–machine integration" between the operator and the free arm.

The application of a 5G-powered robot-assisted teleultrasound diagnostic system in the intensive care unit was associated with the benefits of ease of operation, a simple process, clear images, essentially comparable diagnostic results to bedside examination, no significant difference in diagnostic level, high levels of safety, a reduction in the risk of infection for both the patient and the ultrasound physician, and good feasibility, which deserves to be used widely in clinical practice.