Technology Acceptance Model for Exoskeletons for Rehabilitation of the Upper Limbs from Therapists’ Perspectives
Abstract
:1. Introduction
2. Related Works
2.1. Technology Acceptance Studies
- External predictors or prior factors: These have a direct effect on the perceived usefulness and the perceived ease of use variables. They include self-confidence in technology, prior usage, and anxiety towards a technology.
- Factors coming from other theories: These should increase the reliability of the model. Subjective norms, risk, trust, expectations, and user participation belong to this category.
- Contextual factors: Gender, technological characteristics, and cultural diversity can influence the global effects of the model.
2.2. The TAM Applied to Healthcare Technologies
3. Methods
3.1. A Novel Point of View
3.2. Data Collection
- Intention to use—ITO: Independent variable and output of the model;
- Perceived usefulness—PU: How useful the therapists perceive an exoskeleton to be in supporting part of their rehabilitation sessions;
- Perceived ease of use—EOU: Level of ease of use of the robotic system in terms of both setting and application during the therapy;
- Subjective norm: The extent to which the opinions and suggestions received from other people (e.g., patients, doctors, and other people who the compiler of the application deems reliable) are favorable to the use of exoskeletons;
- Willingness to interact: How much do the therapists that are interviewed consider it desirable to interact with the system and to be personally involved in the robotic therapy?
- Anxiety: How much do the participants fear that the use of exoskeletons is a source of risk for patients or has negative effects on the therapy?
- Time saving: level of perception of an exoskeleton as helpful in saving time and working with more patients;
- Effort saving: Level of perception of an exoskeleton as helpful in reducing the physical burden on therapists during the execution of rehabilitation exercises.
3.3. Data Analysis
- Cronbach’s alpha: We evaluated Cronbach’s alpha for each variable of the model. Cronbach’s alpha is a measure of reliability used to assess the internal consistency of the answers given to questions belonging to the same category. Acceptable reliability is represented by values of alpha ranging from around 0.7 to 0.95 [26].
- Consistency adjustments: If some categories obtained alphas lower than 0.7, we further investigated them. We removed the questions that, from an inner correlation study, were revealed to be uncorrelated with the other questions belonging to the same group (under the acceptability threshold of for Pearson’s coefficient [27]). If the correlation values were acceptable, we kept the questions in the dataset. We concluded by checking whether defections actually improved the alphas of the various categories.
- Pearson’s pairwise correlation: For every category, we evaluated the mean score from the answers provided by each participant. The literature is unclear about the use of the mean value rather than the median when studying Likert-type categories data [28]. Given that no agreement seems to have been reached, we tried to be consistent with Davis’s work, which carried out TAM analyses by using mean scores, Pearson’s correlation, and multiple linear regression [14,23]. Using the mean data, we built a correlation matrix to highlight the correlations between the variables involved in the TAM. We studied Pearson’s coefficients and their statistical significance through an evaluation of their p-values [23].
- Multiple regression model: We created a multiple regression model with the variables of the TAM. ITO was our output variable, while the other categories were the regressors [23].
- Effects of control variables: Given that the control variables could influence the results of our model, we decided to divide the data coming from people who had a previous experience with rehabilitation exoskeletons (for both upper and lower limbs) from the data coming from those who did not. In both cases, we analyzed the correlations between the variables and studied the differences.
4. Results
4.1. Participants and Answers
4.2. Results of the Data Analysis
4.2.1. Cronbach’s Alpha and Consistency Adjustments
4.2.2. Pearson’s Correlation
4.2.3. Effects of Control Variables
4.2.4. Experience
4.2.5. Age
4.2.6. Multiple Regression Model
5. Discussion
- As we can see from the global correlation model, the perceived usefulness of the exoskeleton explained the majority of the variance of the output (around 77%). This correlation value did not change much when splitting the dataset and comparing the results for the two experience subgroups. This point is in agreement with the results obtained from the analysis of patients’ opinions about exoskeletons [12]. The regression coefficient for perceived usefulness was , and it had two-tailed significance. We conclude that, from therapists’ perspectives, the first requirement to be considered for application during everyday rehabilitation sessions is to perceive exoskeletons as useful instruments. Nowadays, various benchmarking frameworks are used to evaluate the efficacy of rehabilitation for the motor abilities of neurological patients [29]. They include the use of multiple sensors: from EMG sensors for muscular activation to optoelectronic systems and inertial measurement units for kinematic performance. Applying these systems to the measurement of the improvement of patients who used a rehabilitation robot for their treatment could increase the level of usefulness perceived by therapists.
- The correlations of time saving and effort saving with PU showed Pearson’s coefficients that are, respectively, equal to and , and both correlations were significant. The beta coefficient of effort saving was statistically significant, while that related to time saving was lower than the acceptability threshold of 0.05. Overall, we can infer that therapists tend to find a robotic system that is able to reduce their physical effort in the execution of the rehabilitation exercises slightly more useful than one that makes them save time (i.e., allowing them to treat a patient while a second one uses the exoskeleton for his/her therapy session).
- The effect of ease of use on the output variable in our model proved to be lower than that of perceived usefulness. The correlation between ease of use and ITO was, in any case, higher for inexperienced therapists, who may have been held back by the prospect of a system that was too complex to learn to use (especially if they did not know about its advantages).
- The correlation between anxiety towards the technological system and ITO, as can be guessed, was negative (and so was the coefficient). It is interesting to notice that for participants who had already experienced the use of an exoskeleton for their sessions, the negative effect of the anxiety variable on ITO was reduced by about 12%. This information suggests that the use of robotic systems for rehabilitation could be encouraged if therapists have the chance of getting in contact with this kind of technology. Raising the public’s level of knowledge, at least in hospitals and rehabilitation centers, could be a good way to increase the level of confidence in this technology and reduce apprehension in those who do not know how it works. In general, it is important to find methods for reducing the negative impact that the fear of not being able to control the therapy has on the willingness to use robotic systems. As we can understand from the answers collected for Q7 and Q9 (see Appendix A.1), therapists’ anxiety was caused by the fact that they felt that they would have no information about how a session conducted by a robot was proceeding if they did not continuously observe the patient. This leads to us losing the advantage in terms of time represented by making one patient use the robot while we work on another patient. An efficient solution to this problem could be investing in complete systems of sensors to be coupled with the exoskeletons and provide reliable and remote feedback to therapists. Other studies proved that feedback is crucial for therapists; rehabilitation experts think that having information about muscular activation and joint positions could be very useful in assessing a patient’s conditions [30]. In this sense, surface electromyography sensors can be integrated into the structure of the robot to record the amount of muscular participation of the patients [31]. Precise position sensors can provide real-time information on the 3D configuration of the arm of the patient. Compact force sensors at the interface with the robot [32] can be used to tune the level of assistance provided by the exoskeleton and assure the therapist that the patient is not harmed. The work described in [33] already moves in this direction; it presented a telerehabilitation system that collected haptic data from the interaction between a patient and a robot and provided them to therapists, who felt confident about being distant from the user while they performed rehabilitation with the device.
- When studying the results of the relation between the subjective norm and the output variable, we could observe that participants’ intention to use exoskeletons had a significant positive correlation with the opinions and suggestions received by doctors and patients (as indicated in the questions that we proposed). The effect of others’ opinions on the use of robots for rehabilitation was reduced by almost 18% for the respondents to the survey who had already used such systems. It also seemed to be reduced when studying the answers of younger therapists, who were more experienced with technologies such as exoskeletons.
- The questions that we proposed that were related to the willingness to interact category aimed to understand if the therapists preferred dealing with robotic systems that gave them many chances for interaction and personalization of the therapy or leaving the exoskeletons in charge of the organization of the entire therapy. We wanted to understand whether it is better to invest in autonomous devices or if it is preferable to find new ways to make therapists cooperate and exchange information with robots. The correlation analysis between willingness to interact and intention to use produced a Pearson’s coefficient that was statistically irrelevant for inexperienced participants (). In any case, the correlation increased by 25.8% when studying the answers provided by therapists who had already used an exoskeleton before compiling the questionnaire (). We can infer that if inexperienced clinicians prefer the advantages offered by a higher level of automatization of the therapy, therapists who have already come into contact with exoskeletal technology consider collaborating with the system more relevant.
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
TAM | Technology acceptance model |
PU | Perceived usefulness |
EOU | Perceived ease of use |
ADL | Activity of daily living |
ITO | Intention to use |
Appendix A. Research Methods
Appendix A.1. Questionnaire
- Welcome to the questionnaire “Exoskeletons for the rehabilitation of the upper limb: therapists’ usability”. This survey is part of a research project that is being conducted by our university as part of the realization of exoskeletons for the neuro-rehabilitation of the upper limbs. The questionnaire is anonymous and aimed at healthcare personnel working in the rehabilitation field.
- By answering the following questions, you will help us understand what the most critical needs that we should satisfy to realize a robotic system for rehabilitation that is useful and appreciated by therapists are.
- Have you ever worked/are you working in an environment in which this kind of technology for rehabilitation is used?
- Have you ever used this kind of technology with your patients?
- Have you ever used similar technologies, such as exoskeletons, for the rehabilitation of a hand or a lower limb?
- Q1: I think that performing some sessions with the help of an exoskeleton for rehabilitation could make the treatment provided to the patients more effective.
- Q2: I am afraid that my patient could be hurt if I leave him/her alone during the session with the exoskeleton.
- Q3: I’d like to use/I’d love to continue using exoskeletal systems during some of the therapy sessions that I perform with my patients.
- Q4: I’d like to integrate the use of an exoskeleton for rehabilitation into the exercises that I propose to my patients daily.
- Q5: I think that the use of an exoskeleton makes the therapy sessions less tiring for me.
- Q6: I think that using an exoskeleton does not require too much concentration effort on my side.
- Q7: I am afraid that the therapy may not go as planned if I do something else while the patient is using the exoskeleton.
- Q8: I believe it is positive to be able to save time by dedicating myself to one patient while another performs the therapy while wearing the exoskeleton.
- Q9: I am afraid that, if I leave my patient alone while using the exoskeleton, the therapy session may not have the effects that I hope for.
- Q10: I appreciate the fact that the exoskeleton gives me the chance to work on more than one patient at the same time.
- Q11: I think that introducing some therapy sessions that use an exoskeleton would improve the overall effect of my physiotherapy treatments.
- Q12: I believe that I could understand how to approach the technology proposed by an exoskeleton without any problem.
- Q13: My patients would like me to offer physiotherapy sessions carried out with the aid of exoskeletons for rehabilitation.
- Q14: The doctors who treat my patients expect me to offer physiotherapy sessions carried out with the aid of exoskeletons for rehabilitation.
- Q15: I appreciate that a robotic system has many parameters and functionalities to be tuned, so the therapy is sure to be personalized according to my needs.
- Q16: I think that the use of an exoskeleton for rehabilitation would make my job easier.
- Q17: Clinical studies indicate that I should use exoskeletons for rehabilitation in my physiotherapy sessions, and therefore, I am inclined to use them.
- Q18: I am afraid that the exoskeleton could cause damage to the patient if I do not monitor it carefully.
- Q19: My patients expect me to offer them physiotherapy sessions carried out with the aid of exoskeletons for rehabilitation.
- Q20: The doctors who treat my patients would like me to offer physiotherapy sessions carried out with the aid of exoskeletons for rehabilitation.
- Q21: I appreciate that the exoskeletal structure supports and moves the patient’s limbs in my place.
- Q22: I would like to be the one in charge of deciding how to regulate the behavior of the exoskeleton based on my perception of the conditions of the patient.
- Q23: I prefer to have direct control over the course of therapy, without letting a device make decisions for me.
- Q24: I am aware of scientific studies that highlight the benefits of using exoskeletons for rehabilitation, and therefore, I am inclined to use them in my work.
- Q25: I appreciate the possibility that an exoskeleton has many parameters and functions to adjust so that I can be sure that the therapy is tailored to my needs.
- Age;
- Gender;
- Educational qualification;
- Job;
- Relationship with technology:
- –
- I like using electronic devices (smartphone, computer, tablet, etc.);
- –
- I always do my best to learn how to use a new technology that I am not familiar with;
- –
- I think technology is really important in our everyday life;
- –
- I am familiar with technological devices (computer, mobile telephone, etc.).
References
- Perry, J.; Rosen, J.; Burns, S. Upper-Limb Powered Exoskeleton Design. Mechatron. IEEE/ASME Trans. 2007, 12, 408–417. [Google Scholar] [CrossRef]
- Zimmermann, Y.; Forino, A.; Riener, R.; Hutter, M. ANYexo: A Versatile and Dynamic Upper-Limb Rehabilitation Robot. IEEE Robot. Autom. Lett. 2019, 4, 3649–3656. [Google Scholar] [CrossRef]
- Nef, T.; Klamroth-Marganska, V.; Riener, R. ARMin—Exoskeleton Robot for Stroke Rehabilitation; Springer: Berlin/Heidelberg, Germany, 2010; Volume 25, pp. 127–130. [Google Scholar] [CrossRef]
- Gasperina, S.D.; Longatelli, V.; Panzenbeck, M.; Luciani, B.; Morosini, A.; Piantoni, A.; Tropea, P.; Braghin, F.; Pedrocchi, A.; Gandolla, M. AGREE: An upper-limb robotic platform for personalized rehabilitation, concept and clinical study design. In Proceedings of the 2022 International Conference on Rehabilitation Robotics (ICORR), Rotterdam, The Netherlands, 25–29 July 2022; pp. 1–6. [Google Scholar] [CrossRef]
- Mehrholz, J.; Pohl, M.; Platz, T.; Kugler, J.; Elsner, B. Electromechanical and robot-assisted arm training for improving activities of daily living, arm function, and arm muscle strength after stroke. Cochrane Database Syst. Rev. 2015. [Google Scholar] [CrossRef] [PubMed]
- Maier, M.; Ballester, B.; Verschure, P. Principles of Neurorehabilitation After Stroke Based on Motor Learning and Brain Plasticity Mechanisms. Front. Syst. Neurosci. 2019, 13, 74. [Google Scholar] [CrossRef] [PubMed]
- Mehrholz, J.; Todhunter-Brown, A.; Pohl, M.; Kugler, J.; Elsner, B. Systematic review with network meta-analysis of randomized controlled trials of robotic-assisted arm training for improving activities of daily living and upper limb function after stroke. J. Neuroeng. Rehabil. 2020, 17, 83. [Google Scholar] [CrossRef] [PubMed]
- Rose, C.G.; Deshpande, A.D.; Carducci, J.; Brown, J.D. The road forward for upper-extremity rehabilitation robotics. Curr. Opin. Biomed. Eng. 2021, 19, 100291. [Google Scholar] [CrossRef]
- Marangunić, N.; Granić, A. Universal Access in the Information Society International Journal Technology acceptance model: A 521 literature review from 1986 to 2013. Univers. Access Inf. Soc. 2014, 14, 1–15. [Google Scholar] [CrossRef]
- Davis, F.D. Perceived Usefulness, Perceived Ease of Use, and User Acceptance of Information Technology. MIS Q. 1989, 13, 319–340. [Google Scholar] [CrossRef] [Green Version]
- Jankowski, N.; Ivanova, E.; Wiehe, L.; Wahl, M. Long-term changes in technology acceptance of a robotic system in stroke treatment: A pilot study. Curr. Dir. Biomed. Eng. 2020, 6, 20202012. [Google Scholar] [CrossRef]
- Onofrio, R.; Gandolla, M.; Lettieri, E.; Pedrocchi, A. Acceptance Model of an Innovative Assistive Technology by Neurological Patients with a Motor Disability of Their Upper Limb; Springer: Cham, Switzerland, 2020; pp. 907–913. [Google Scholar] [CrossRef]
- Shore, L.; Power, V.; de Eyto, A.; O’Sullivan, L. Technology Acceptance and User-Centred Design of Assistive Exoskeletons for Older Adults: A Commentary. Robotics 2018, 7, 3. [Google Scholar] [CrossRef]
- Davis, F.D. User Acceptance of Information Technology: System Characteristics, User Perceptions and Behavioral Impacts. Int. J. Man Mach. Stud. 1993, 38, 475–487. [Google Scholar] [CrossRef]
- King, W.; He, J. A meta-analysis of the Technology Acceptance Model. Inf. Manag. 2006, 43, 740–755. [Google Scholar] [CrossRef]
- AlQudah, A.A.; Al-Emran, M.; Shaalan, K. Technology Acceptance in Healthcare: A Systematic Review. Appl. Sci. 2021, 11, 10537. [Google Scholar] [CrossRef]
- Tam, L.; Khosla, R. Using assistive social robots in health settings: Implications of personalization for human-machine communication. Communication 2016, 5, 9. [Google Scholar]
- Mois, G.; Beer, J. The Role of Healthcare Robotics in Providing Support to Older Adults: A Socio-ecological Perspective. Curr. Geriatr. Rep. 2020, 9, 82–89. [Google Scholar] [CrossRef]
- He, Y.; He, Q.; Liu, Q. Technology Acceptance in Socially Assistive Robots: Scoping Review of Models, Measurement, and Influencing Factors. J. Healthc. Eng. 2022, 2022, 6334732. [Google Scholar] [CrossRef]
- Turja, T.; Aaltonen, I.; Taipale, S.; Oksanen, A. Robot acceptance model for care (RAM-care): A principled approach to the intention to use care robots. Inf. Manag. 2020, 57, 103220. [Google Scholar] [CrossRef]
- Nertinger, S.; Kirschner, R.; Naceri, D.; Haddadin, S. Acceptance of Remote Assistive Robots with and without Human-in-the-Loop for Healthcare Applications. Int. J. Soc. Robot. 2022. [Google Scholar] [CrossRef]
- Hall, A.K.; Backonja, U.; Painter, I.; Cakmak, M.; Sung, M.; Lau, T.; Thompson, H.J.; Demiris, G. Acceptance and perceived usefulness of robots to assist with activities of daily living and healthcare tasks. Assist. Technol. 2019, 31, 133–140. [Google Scholar] [CrossRef] [PubMed]
- Yousafzai, S.; Foxall, G.; Pallister, J. Technology acceptance: A meta-analysis of the TAM: Part 2. J. Model. Manag. 2007, 2, 281–304. [Google Scholar] [CrossRef]
- Paluri, R.; Mehra, S. Exploring the acceptance for e-learning using technology acceptance model among university students in India. Int. J. Process Manag. Benchmarking 2015, 5, 194–210. [Google Scholar] [CrossRef]
- Zhao, J.; Fang, S.; Jin, P. Modeling and Quantifying User Acceptance of Personalized Business Modes Based on TAM, Trust and Attitude. Sustainability 2018, 10, 356. [Google Scholar] [CrossRef]
- Tavakol, M.; Dennick, R. Making Sense of Cronbach’s Alpha. Int. J. Med. Educ. 2011, 2, 53–55. [Google Scholar] [CrossRef]
- Ratner, B. The correlation coefficient: Its values range between +1/-1, or do they? J. Target. Meas. Anal. Mark. 2009, 17. [Google Scholar] [CrossRef]
- Jamieson, S. Likert Scales: How to (ab) Use Them. Med. Educ. 2005, 38, 1217–1218. [Google Scholar] [CrossRef]
- Longatelli, V.; Torricelli, D.; Tornero, J.; Pedrocchi, A.; Molteni, F.; Pons, J.; Gandolla, M. A unified scheme for the benchmarking of upper limb functions in neurological disorders. J. Neuroeng. Rehabil. 2022, 19, 102. [Google Scholar] [CrossRef]
- Lu, E.C.; Wang, R.H.; Hebert, D.; Boger, J.; Galea, M.P.; Mihailidis, A. The development of an upper limb stroke rehabilitation robot: Identification of clinical practices and design requirements through a survey of therapists. Disabil. Rehabil. Assist. Technol. 2011, 6, 420–431. [Google Scholar] [CrossRef] [PubMed]
- Steele, K.; Papazian, C.; Feldner, H. Muscle Activity After Stroke: Perspectives on Deploying Surface Electromyography in Acute Care. Front. Neurol. 2020, 11, 576757. [Google Scholar] [CrossRef]
- Choi, H.; Seo, K.; Hyung, S.; Shim, Y.; Lim, S.C. Compact Hip-Force Sensor for a Gait-Assistance Exoskeleton System. Sensors 2018, 18, 566. [Google Scholar] [CrossRef]
- Baur, K.; Rohrbach, N.; Hermsdörfer, J.; Riener, R.; Klamroth-Marganska, V. The “Beam-Me-In Strategy”—Remote haptic therapist-patient interaction with two exoskeletons for stroke therapy. J. Neuroeng. Rehabil. 2019, 16, 85. [Google Scholar] [CrossRef]
- Hancock, P.; Kessler, T.; Kaplan, A.; Brill, J.; Szalma, J. Evolving Trust in Robots: Specification through Sequential and Comparative Meta-Analyses. Hum. Factors J. Hum. Factors Ergon. Soc. 2020, 63, 001872082092208. [Google Scholar] [CrossRef] [PubMed]
- Koren, Y.; Feingold Polak, R.; Levy-Tzedek, S. Extended Interviews with Stroke Patients Over a Long-Term Rehabilitation Using Human–Robot or Human–Computer Interactions. Int. J. Soc. Robot. 2022, 14, 1–19. [Google Scholar] [CrossRef] [PubMed]
Study | Author and Date | Technology | Point of View |
---|---|---|---|
[19] | He et al., 2022 | Social robots in elderly care facilities | Elderly people |
[20] | Turja et al., 2020 | Service robots | Healthcare professionals (nurses and doctors) |
[21] | Nertinger et al., 2022 | Remote assistive robots (Humanoids) | Adult patients |
[11] | Jankowski et al., 2020 | Rehabilitation end-effector (Bi-Manu-Interact robot) | Stroke patients |
[22] | Hall et al., 2019 | Assistive robots for activities of daily living | Patients |
[13] | Shore et al., 2018 | Assistive exoskeletons | Elderly people |
[12] | Onofrio et al., 2020 | Assistive technologies for neurological motor impairments | Neurological patients |
Category (Variable) | No. of Questions |
---|---|
Intention to use | 2 |
Perceived usefulness | 3 |
Anxiety | 4 |
Time saving | 2 |
Effort saving | 2 |
Subjective norm | 6 |
Perceived ease of use | 2 |
Willingness to interact with the system | 4 |
Information | Answer |
---|---|
Age | Mean: 37.4 ± 10.1 y.o. Range: 23–59 y.o. Median: 35 y.o |
Gender | • 23 men • 31 women • 1 other |
Occupation | • 3 occupational therapists • 3 physiatrists • 1 clinical researcher in physiotheraphy • 48 physiotherapists |
Already knew what an exoskeleton is? | • 54 yes • 1 no |
Already used an exoskeleton? | • 31 yes • 24 no |
ITO | PU | ANX | TS | ES | SUBN | EOU | WTI | |
---|---|---|---|---|---|---|---|---|
0.865 | 0.829 | 0.795 | 0.674 | 0.464 | 0.705 | −0.123 | 0.424 |
Int. to Use | Perc. Useful. | Anxiety | Time Saving | Effort Saving | Subj. Norm | Ease of Use | Will. to Interact | |
---|---|---|---|---|---|---|---|---|
Intention to use | 1 | 0.765 ** | −0.153 * | 0.221 | 0.359 | 0.440 ** | 0.347 ** | 0.230 * |
Perceived Usefulness | 0.765 | 1 | −0.273 | 0.408 ** | 0.582 ** | 0.312 | 0.367 | 0.168 |
Independent Variable | Dependent Variable | Pearsons’s Coefficient | ||
---|---|---|---|---|
Global | Already Used | Never Used | ||
Perc. usefulness | ITO | 0.765 | 0.796 | 0.719 |
Anxiety | ITO | −0.153 | −0.105 | −0.221 |
Subj. norm | ITO | 0.440 | 0.411 | 0.589 |
Ease of use | ITO | 0.347 | 0.352 | 0.414 |
Will. to interact | ITO | 0.230 | 0.347 | 0.089 |
Time saving | PU | 0.408 | 0.522 | 0.249 |
Effort saving | PU | 0582 | 0.708 | 0.322 |
Younger Group | Intermediate Group | Older Group | |
---|---|---|---|
Perceived usefulness | 0.881 | 0.722 | 0.545 |
Subjective norms | 0.290 | 0.370 | 0.551 |
Independent Variable | Dependent Variable | SE | tStat | p Values | |
---|---|---|---|---|---|
Perc. Usefulness | ITO | 0.7090 | 0.0981 | 7.2302 | |
Ease of Use | ITO | 0.0228 | 0.0891 | 0.2556 | 0.7993 |
Subj. Norm | ITO | 0.2794 | 0.1249 | 2.2423 | 0.0295 |
Will. to Interact | ITO | 0.2098 | 0.1341 | 1.5643 | 0.0422 |
Anxiety | ITO | −0.0154 | 0.0893 | −0.1720 | 0.8642 |
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Luciani, B.; Braghin, F.; Pedrocchi, A.L.G.; Gandolla, M. Technology Acceptance Model for Exoskeletons for Rehabilitation of the Upper Limbs from Therapists’ Perspectives. Sensors 2023, 23, 1721. https://doi.org/10.3390/s23031721
Luciani B, Braghin F, Pedrocchi ALG, Gandolla M. Technology Acceptance Model for Exoskeletons for Rehabilitation of the Upper Limbs from Therapists’ Perspectives. Sensors. 2023; 23(3):1721. https://doi.org/10.3390/s23031721
Chicago/Turabian StyleLuciani, Beatrice, Francesco Braghin, Alessandra Laura Giulia Pedrocchi, and Marta Gandolla. 2023. "Technology Acceptance Model for Exoskeletons for Rehabilitation of the Upper Limbs from Therapists’ Perspectives" Sensors 23, no. 3: 1721. https://doi.org/10.3390/s23031721
APA StyleLuciani, B., Braghin, F., Pedrocchi, A. L. G., & Gandolla, M. (2023). Technology Acceptance Model for Exoskeletons for Rehabilitation of the Upper Limbs from Therapists’ Perspectives. Sensors, 23(3), 1721. https://doi.org/10.3390/s23031721