Design of SpringExo

The passive SpringExo in Figure 2 is a 3D-printed nylon spring coil attached to a photopolymer resin 3D-printed thigh cuff and shank cuff, which can strap to the thigh and shank of the user. The coil spring can accommodate extreme knee flexion in squat kinematics, such as in Tewart (Reference Tewart2012). The cuffs are mechanically connected to the spring ends and attached to the leg via Velcro straps covering the skin to avoid discomfort. The coils do not collide when a user performs a squat as they both revolve in the same direction. The complete assembly weighs 450 g. The exoskeleton is easily donned and doffed while securing the leg. A user wearing the SpringExo is shown in Figure 3. The parts and instrumented treadmill used in this study are labeled.

Figure 3. A user performing a squat in the SpringExo passive exoskeleton. The instrumented treadmill is used to collect foot pressure and loading data. The motion of the human body is captured using infrared markers. Surface EMG signals are used to collect muscle activation data.

The SpringExo only assists in knee extension during the ascent part of the squat cycle while the energy is stored during descent. The spring bending angle $ \varphi $ compresses the spring and results in the Force $ {F}_s $ acting on the thigh. The angle $ \varphi $ is the central spring angle defined as:

(1) $$ \varphi =\pi -{\theta}_{knee}. $$

The spring exerts a force $ {F}_s $ on the leg due to the bending arc of the spring. The net force is composed of a tangential component $ {F}_{sT} $ that supports the leg, and a normal component $ {F}_{sN} $ that provides assistance in leg extension, as shown in Figure 2.

(2) $$ {F}_{sT}={F}_s\cos \frac{\varphi }{2}. $$

(3) $$ {F}_{sN}={F}_s\sin \frac{\varphi }{2}. $$

The Spring mechanism and stored potential energy of this device is described in Sui et al. (Reference Sui, Chang, Hidayah, Zhu and Agrawal2021). We briefly present this mechanism here. The total elastic potential energy $ {E}_{\mathrm{p}} $ stored in the spring comes from compression $ {E}_{\mathrm{c}} $ and bending $ {E}_{\mathrm{b}}. $

(4) $$ {E}_{\mathrm{p}}={E}_{\mathrm{c}}+{E}_{\mathrm{b}}. $$

In compression, the virtual center length of the spring changes from its free length $ {l}_{\mathrm{s}} $ to the arc length $ \overset{\frown }{l} $ , and the elastic potential energy $ {E}_{\mathrm{c}} $ stored in the spring with a stiffness of $ k $ is:

(5) $$ {E}_{\mathrm{c}}=\frac{1}{2}k{\left({l}_{\mathrm{s}}-\overset{\frown }{l}\right)}^2. $$

In bending, according to Kim et al. (Reference Kim, Cheng, Diakite, Gullapalli, Simard and Desai2017), Gutkowski (Reference Gutkowski1998), and Wahl (Reference Wahl1963), the total stored potential energy $ {E}_{\mathrm{b}} $ due to the spring bending with a constant arc length $ \overset{\frown }{l} $ is expressed as:

(6) $$ {E}_{\mathrm{b}}={\int}_{\overset{\frown }{l}}\frac{\beta }{2}{\left(\frac{\mathrm{d}\varphi }{\mathrm{d}s}\right)}^2\mathrm{d}s, $$

(7) $$ \beta =\frac{2\overset{\frown }{l} EIG}{\pi {nr}_{\mathrm{c}}\left(2G+E\right)}, $$

where $ \beta $ , $ E $ , $ I $ , $ G $ , $ {r}_{\mathrm{c}} $ , $ n $ , and $ \mathrm{d}s $ are, respectively, the flexural rigidity of the spring, Young’s modulus, area moment of inertia, shear modulus, mean radius of the spring coil, number of the spring coil, and element of the arc length $ \overset{\frown }{l} $ . According to equations (4)–(7), $ \mathrm{d}s=R\mathrm{d}\varphi $ , and the geometric relationship in Figure 2a, the total stored elastic potential energy $ {E}_{\mathrm{p}} $ is expressed as:

(8) $$ {E}_{\mathrm{p}}=\frac{1}{2}{kl}_{\mathrm{s}}^2{\left(1-\frac{1}{2}\frac{\varphi }{\tan \frac{\varphi }{2}}\right)}^2+\frac{\varphi^2 EIG}{2\pi {nr}_{\mathrm{c}}\left(2G+E\right)}. $$

The SpringExo has an outer diameter $ D $  = 167 mm, a coil diameter of $ d $  = 16.5 mm. Nylon-66’s has a Flexural Modulus $ \beta $ of 2,700 Nmm⁻², and Young’s modulus $ E $ of 3.7 Gpa. The analysis and optimization of these parameters for SpringExo stiffness are not included in this work.

Subjects

A convenience sample of seven healthy subjects (four females)—age 25.9 ± 2.2 years, height 167.6 cm ± 4.6 cm, and mass 54.3 kg ± 5.8 kg—were recruited to carry out the study. Investigators collected informed consent from subjects in the study approved by the Institutional Review Board of Columbia University.

Experimental Setup and Protocol

Subjects performed squatting motions on an instrumented treadmill (Pluto, HP Cosmos, Nußdorf, Germany) with an integrated pressure sensor to measure foot pressure at a frequency of 100 Hz. Markers were placed on the distal phalanges, ankle, heel, tibia, knee, femur, and trochanter to capture knee motion data at 200 Hz (Vero, Vicon, Oxford, United Kingdom). Wireless EMGs were placed on the rectus femoris and bicep femoris muscles. These data were captured at 2,000 Hz (Trigno, Delsys, Cambridge, MA) in the marked positions shown in Figure 3.

A baseline (B) condition where the subjects performed squats wearing no device was compared against the condition where the SpringExo exoskeleton was worn (E). Subjects completed squat cycles at their own pace in each condition. Subjects were assigned either the B or E condition in a random order. Each measurement started and ended with the subjects standing neutrally and at rest. Subjects did not acclimatize to the springs by practicing with the design and performed the squats directly after donning the device. Investigators instructed subjects to squat continuously until tired. The first five squat cycles were discarded. The next 20 cycles from each subject were analyzed and interpreted.

Data Processing

All data preparation and processing was done using Python 3.6 (Python, Wilmington, DE). Kinematics of the knee joint was solved using the marker set on the leg. Markers attached to the hip were used to segment each squat cycle, where the upright position was used as an endpoint. Each segment’s EMG data and joint angles from both legs were normalized into a cycle, where 0% indicates the initial standing position, 25% indicated halfway through descent, 50% indicates the lowest position, 75% indicates halfway through ascent, and 100% indicates the terminal standing position. A fourth-order band-pass (20–400 Hz) Butterworth filter was used to filter the raw EMG signals, rectified and passed through another fourth-order low-pass (3 Hz) Butterworth filter. Each subject’s cycles were B-normalized using the subject’s maximum muscle activation values in B sessions.

Each subject’s EMG signals were normalized by their respective B maximum values. All subjects’ knee flexion angles, normalized rectus femoris (nRF), and normalized bicep femoris profiles were averaged across both legs. These profiles were used to calculate averages, maxima, and the descent and ascent values for each parameter. The knee kinematics and muscle activations of each mode compare the effect of the worn SpringExo on user biomechanics during a squat exercise.

The foot pressure maximum at the ball and the heel of the foot were found for each cycle. The loading line length and stance width of the feet were also extracted across the same cycles. Differences in these parameters between the two conditions indicate the effects of wearing the SpringExo on the user’s overall foot placement patterns. Differences in overall foot loading and placement indicate changes that can adversely affect the person’s safety and comfort in performing the squatting task.

Statistical Analysis

The mean values, maximum values, minimum values, values at 25% and 75% of the squat cycle, and their standard deviations to the mean were calculated for knee flexion, muscle activations, and foot loading parameters. Each cycle’s values for each subject were grouped according to the mode B or E. The data were tested for normality using Kolmogorov–Smirnov one-sample tests. The data violated normality, and so nonparametric tests were selected to compare the conditions. A Mann–Whitney U test was used to compare the values reported in this paper. Significance was set at $ \alpha =0.05. $