Table 2.
Characteristics of the observational studies included in the review.
| Author, Year, Country |
Method. Quality | Population (Pathology, Age—Years) | Intervention (Type, Sessions, Length, Frequency, Total Duration) | Comparison | Delivery Method | Main Outcomes | Conclusion |
|---|---|---|---|---|---|---|---|
| Cancino- López et al. (2021) Chile [29] |
STROBE Checklist 18/22 | 50 COVID-19 patients (54.1 ± 15.4) |
24 exercise sessions of 50–60 min each (10 min warm up, 25 min resistance training, 10 min aerobic training, 5 min cool down), 2–3×/week, via video calls | (No comparison) | Synchronous | Functionality (Barthel’s index) and physical fitness (2 min step test), elbow flexion—one repetition maximum (1RM), short physical performance battery, hand grip strength, 30 s chair stand, skeletal muscle index, body fat percentage, resting pulse, arterial blood pressure and pulse oximetry | 24 sessions of in-home telerehabilitation exercise program promoted the recovery of physical independence, with significant improvements in functionality and physical fitness (p < 0.0001). |
| De Marchi et al. (2020) Italy [30] |
STROBE Checklist 19/22 | 19 patients with ALS (51.48) | Televisit of 80–120 min, 3×/month for 3 months (multidisciplinary approach: neurologist, dietician, psychologist, physiotherapist) | (No comparison) | Synchronous | Anxiety and depression (HADS and ALSAQ-40), functional status (ALSFRS-R, Barthel scale), exertion (Borg scale) and pain intensity (VAS) | ALS patients managed by telemedicine received a comparable quality of care to those seen via traditional face-to-face methods; this needs to become an integrated platform for delivering high-quality tertiary ALS care. |
| Lamberti et al. (2021) Italy [31] |
STROBE Checklist 21/22 | 66 patients with peripheral artery disease (PAD) (72) | 2 × 8 min daily sessions of slow intermittent in-home walking. Additional regular phone calls to check in on patients | (No comparison) | Synchronous | 6MWD, pain-free walking distance, body weight blood pressure, ankle–brachial index | Pain-free walking distance improved significantly (p < 0.001), body weight decreased, while 6MWD, blood pressure and ankle–brachial index remained stable. A structured in-home walking program guided by phone was adhered to by patients with PAD and improved their mobility. |
| Milani et al. (2021) Italy [32] |
STROBE Checklist 19/22 | 23 patients with physical disabilities (44–70.6) | Physiotherapist-led telerehabilitation program with customized exercises; 1 h sessions 2–3 times/week from March to May 2020, delivered in real time via Skype | No tele-rehabilitation | Synchronous | Feasibility and acceptability | Telerehabilitation was a feasible solution, with high adherence and well accepted by patients. |
| Negrini et al. (2020) Italy [33] |
STROBE 16/22 | 1207 patients with spinal disorders, (3–18) | Teleconsultations and telephysiotherapy delivered over 3 weeks (15 working days) | Traditional in-person physiotherapy (13 working days) |
Mixed | Number of services provided and patient satisfaction | Telephysiotherapy was feasible and allowed health professionals to continue providing outpatient services with a high patient satisfaction, reducing face-to-face contact and the need for travel to a minimum. |
| Oprandi et al. (2021) Italy [34] |
STROBE Checklist 19/22 | 13 children and young adults with acquired brain injury (ABI) (10.7) | Neuropsychological and speech telerehabilitation sessions (2×/week for 10 weeks) | (No comparison) | Synchronous | Feasibility and acceptability | Feasibility and acceptability of synchronous telerehabilitation for young patients with ABI was demonstrated. Telerehabilitation can be a successful intervention for this population. |
| Patel et al. (2021) India [35] |
STROBE Checklist 16/22 | 47 patients (23 cardio-vascular, 15 pulmonary, 9 oncology) (61.2 ± 12.5) | Exercise telerehabilitation program (5–10 min warm-up, 20–25 min aerobic and strengthening exercises; plus +30 min brisk walk); 3×/week for 1 month | (No comparison) | Synchronous | 6MWT, HRQL (FACIT), daily step count | A short-term, supervised telerehabilitation program yielded significantly positive effects on 6MWT (p = 0.0418) and HRQL (p = 0.0313) in cardiac, pulmonary and oncology patients during COVID-19. |
| Romano et al. (2021) Italy [36] |
STROBE Checklist 20/22 | 13 patients with Rett syndrome (RTT) (17 y 11 m) |
3-month home-based, individualized rehabilitation program of motor activities, remotely supervised via Skype calls | (No comparison) | Synchronous | Gross motor function | A total of 76.9% of participants significantly increased their gross motor function. A high level of usefulness, adherence and general satisfaction was observed. Findings strongly support the implementation of telerehabilitation programs for this population. |
| Sakai et al. (2020) Japan [37] |
STROBE Checklist 18/22 | 43 COVID-19 patients undergoing rehabilitation (21–95) | n = 18 Remote rehabilitation via videocalls on iPad, with exercises to develop strength, endurance, range of motion and flexibility. Daily 20 min sessions for 1 month |
n = 25 In-person rehabilitation with exercises to develop strength, endurance, range of motion and flexibility |
Synchronous | ADLs (Barthel Index), mobility scores | The remote rehabilitation group had significantly higher scores in the Barthel Index than the in-person group. Remote rehabilitation is an effective and safe modality and can facilitate rehabilitation in various situations, including patients that can be treated at a distance. |
| Werneke et al. (2021) USA [22] |
STROBE Checklist 20/22 | 222,680 patients with a variety of conditions (55 ± 18) | Telerehabilitation (6% of all episodes of care) | Traditional in-person visits | Synchronous (60%), asynchronous (21%), mixed (19%) | Physical function, number of visits, patient satisfaction, telerehabilitation frequency and modes | Telerehabilitation rate was 6%, decreasing from 10% to 5% between the second and third quarters of 2020. The rate of patients very satisfied with their treatment was 3% higher for no telerehabilitation. More studies are needed to understand what facilitates and inhibits the use of telerehabilitation by rehabilitation therapists in order to promote it when appropriate. |