Motor Learning in Individuals With Lower Limb Loss and Chronic Diabetes

Not Applicable

• Conditions: Amputation; Diabetes Mellitus; Neuropathy, Diabetic
• Interventions: Behavioral: Instructions to perform a motor task (external vs. internal focus instructions)

• Registration Number: NCT03989063
• Lead Sponsor: University of Nevada, Las Vegas

Brief Summary

Inadequate rehabilitation training after amputation can result in poor patient outcomes, injuries, and wasted healthcare resources. This is a serious public health problem due to an aging population and rising prevalence of diabetes (main cause of amputation in the U.S.). In this study, the investigators will examine the effects of external vs. internal attentional focus instruction on learning of a balance task in individuals with existing amputation and those at risk of amputation (older adults with diabetes). With the proposed research, the investigators aim to expand the understanding of motor learning in individuals with and at risk of lower limb loss to provide knowledge that will lead to more effective and efficient rehabilitation.

Detailed Description

1. Prior to participation in the study, the purpose and procedures of the study, including possible image and video recordings, will be explained to the subjects.

2. Subjects will then be required to give written consent for their participation and will receive a copy of their consent form.

3. The following 2-part research protocol uses a similar experimental protocol (learning a balance task) on individuals with leg amputation (Part 1), and individuals with chronic diabetes (Part 2).

Part 1:

The experiment will take place over a 3-day period including screening and baseline testing (Visit 1), balance training (Visits 2), and retention testing (Visit 3; at least 24 hours after Visit 2). On Visit 1, the investigators will assess aspects of health and functional capacity to assess participation eligibility and establish baseline characteristics of the participants. In addition to medical history and anthropometric measurements, the assessment will consist of clinical surveys of quality of life, physical activity level, balance confidence, and fear of falling. Ambulatory performance will be quantified. Additional amputee-specific measures will be used to assess functional characteristics unique to the population.

The balance training involves standing and maintaining balance on a stabilometer, which consists of a platform (1.3m long by 1.4m wide) connected to a single axis that allows bi-directional sway (Lafayette Instrument Co.; Figure 1). The maximum angular deviation of the platform is 18°. A safety harness is provided to prevent falls but does not provide support during the performance of the task. The load on the harness will be monitored with an S-type strain gauge (Delsys Inc., Massachusetts, USA) connected in series to the harness tether. Participants are required to maintain balance with feet in a medial-lateral orientation while standing on the balance board and looking straight ahead. A potentiometer monitors the sway angle of the platform. An integrated timer measures time in balance, which is defined as when the platform angle is within ± 5° of horizontal.\[52\] The primary outcome measure is time in balance (sec.) for each 30s trial. The secondary outcome measure is platform angular deviation from horizontal (RMSE; degree).

Participants will be assigned to receive the 2 attentional focus conditions in random order. Depending on the condition, participants will receive either internal or the external focus instruction on where to direct their attention while training to perform the balance task. During training, the assigned instruction will be reinforced at the beginning and after every 5 practice trials. After they complete training with the first condition, they will go through a washout period (at least 4 weeks) before receiving training under the other condition. Participants will be blinded to the purpose of the intervention and study design until debriefing at the end of the study.

The training will take place over a 2-day period (Visits 1 and 2), the investigators will monitor the changes in balance task performance over 40 total practice trials (20 trials each visit). The balance training consists of thirty 30s trials with a 90s rest interval between trials. During the rest interval, the platform will be locked to provide a stable surface or the participant can choose to step off the platform to sit down and rest when needed. After each 5 trials, participants will be given feedback regarding their performance (time in balance). No additional feedback will be provided. This protocol has been validated in the older adult population (mean age 69.4 years) in a previous study (Chiviacowsky et al. 2010). After each training block of 5 trials, the participant's self-perceived direction of attentional focus and spontaneous comments during the practice will be checked. The retention test will be performed at least 24 hours after the 2nd training day (Visit 3). The retention test will consist of performing 10 trials of the same balance task during which the participant will not receive any instructions, reminders, or feedback. An additional 10 trials of skill transfer task will be performed with an added cognitive task (counting numbers backward).

Part 2 (individuals with diabetes):

The procedure of Part 2 of this research is identical to Part 1. The main differences, in addition to the different participant population are described below.

In addition to the baseline health and functional capacity assessments as described in Part 1, the investigators will assess all participants' sensorimotor function using an established knee joint reposition sense test on a Cybex Norm dynamometer (Computer Sports Medicine Inc., Stoughton, MA, USA). This test assesses participant's ability to reproduce a joint angle using only proprioception. The test performance will be measured as the absolute error in degrees between the reproduced and target angles. This specific test was chosen to quantify the lower limb sensorimotor function because previous studies have shown it to be predictive of mobility outcomes in older adults in general and in those with diabetes. The investigators will determine individuals with diabetes-related sensorimotor impairment if the error is greater than 3.65°.

Individuals will be randomly assigned to receive either internal or external focus instructions conditions during the balance training. The experimental protocols and procedures will be the same as in Aim 1, including the screening (Visit 1), balance training (Visits 2), and retention and skill transfer testing (Visit 3; at least 24 hours after Visit 2).

Study Timeline

• Study First Submitted: 2019-06-04
• Study First Submitted QC: 2019-06-17
• Study First Posted: 2019-06-18
• Study Start: 2019-10-01
• Status Verified: 2022-07
• Last Update Submitted: 2022-07-27
• Last Update Posted: 2022-07-28
• Primary Completion: 2023-12-31
• Study Completion: 2024-06-30

Recruitment & Eligibility

• Status: UNKNOWN
• Sex: All
• Target Recruitment: 55

Inclusion Criteria

Not provided

Exclusion Criteria

1. Have other concurrent central nervous system diseases that influence motor functions and balance.

2. Have leg/foot ulcer or other conditions that cause pain during weight-bearing.

3. Have cardiovascular, respiratory or other critical health conditions that preclude moderate physical activity.

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Amputees (External Focus)	Instructions to perform a motor task (external vs. internal focus instructions)	Participants in this group will receive the external focus instruction on where to direct their attention while training to perform the balance task. During training, the assigned instruction will be reinforced at the beginning and after every 5 practice trials.
Diabetes (Internal Focus)	Instructions to perform a motor task (external vs. internal focus instructions)	Participants in this group will receive the internal focus instruction on where to direct their attention while training to perform the balance task. During training, the assigned instruction will be reinforced at the beginning and after every 5 practice trials.
Amputees (Internal Focus)	Instructions to perform a motor task (external vs. internal focus instructions)	Participants in this group will receive the internal focus instruction on where to direct their attention while training to perform the balance task. During training, the assigned instruction will be reinforced at the beginning and after every 5 practice trials.
Diabetes (External Focus)	Instructions to perform a motor task (external vs. internal focus instructions)	Participants in this group will receive the external focus instruction on where to direct their attention while training to perform the balance task. During training, the assigned instruction will be reinforced at the beginning and after every 5 practice trials.

Primary Outcome Measures

Name	Time	Method
Change in balance performance	Throughout the balance training period (2 days, up to 40 trials) and during the post-training tests	During each balance practice trial, average deviation of balance platform angle from horizontal will be measured in degrees. Smaller deviation from horizontal indicates better balance performance.

Secondary Outcome Measures

Name	Time	Method
Change in patient's self-reported outcomes	Throughout the balance training period (2 days, assessed every 5 practice trials).	Self-efficacy regarding the performance of the balance task is assessed using a 4-question survey. An example question is: "How confident are you that you can keep yourself in balance for 15 out of 30 seconds?". Participant's response to each question is measured using a 0-10 scale. Higher confidence indicates greater self-efficacy.
Change in fall recovery performance	Before and after the 2-day balance training. The after training assessment will be conducted 2-10 days after the conclusion of the balance training.	Trunk angular velocity during slipping/tripping (degree/second). Previous studies have shown that slower trunk angle change (i.e. lower trunk angular velocity) during simulated tripping/slipping is associated with successful fall recovery. Slower trunk angular velocity indicates better fall recovery performance.

Trial Locations

Locations (1)

University of Nevada, Las Vegas; 🇺🇸 Las Vegas, Nevada, United States