Web Site Accessibility Among Doctor of Physical Therapy Programs in the United States.

INTRODUCTION: Given the impetus to improve accessibility for diverse learners seeking physical therapist education, it is critical that all entry points to access information have minimal barriers. This study identified Web site accessibility barriers among Doctor of Physical Therapy (DPT) programs in the United States. REVIEW OF LITERATURE: Web site accessibility has been evaluated among many institutions of higher education, but none focused on DPT education. Individuals with disabilities may be adversely affected by Web site accessibility barriers. SUBJECTS: This cross-sectional study included 262 DPT programs in the United States. Doctor of Physical Therapy program characteristics collected were geographic region, institutional control type (public/private), medical school affiliation, accreditation status, total institutional enrollment, and DPT class size. METHODS: The Web Accessibility Evaluation (WAVE) Tool assessed data related to accessibility barriers among DPT program homepage Uniform Resource Locators. Three primary outcomes from the WAVE Tool included WAVE Total Errors, Error Density, and Total Alerts. RESULTS: Web site homepage accessibility barriers varied among programs for WAVE Total Errors (range 0-150), Error Density (range 0-14.6%), and Total Alerts (range 1-331). Median Total Errors were greater among private (9.0) versus public (5.0) institution Web sites (P < .001). Median Total Errors were greater among those institutions not affiliated with a medical school (9.0) compared with those that had an affiliated medical school (7.0) (P = .04). No differences in accessibility barriers were identified according to geographic region or accreditation status (P > .05). Median Total Errors were significantly different between institutional enrollment quartiles (H[3] = 17.9, P < .001), with no differences noted between DPT class size quartiles for any outcome (P > .05). Generally, weak-fair inverse correlations were observed between student enrollment for the institution and Web site accessibility barrier outcomes. DISCUSSION AND CONCLUSION: Homepage accessibility barriers varied greatly among DPT programs in the United States. Factors, including being a private institution, no medical school affiliation, and lower institutional enrollment, were related to increased accessibility barriers.

Physical therapy management of an individual with post-COVID fatigue considering emotional health in an outpatient setting: A case report.

PURPOSE: The purpose of this case report is to provide a plan of care with an emphasis on patient education and consideration of emotional health for a patient with post-COVID fatigue in an outpatient setting. CASE DESCRIPTION: A 50-year-old woman, ten-weeks post-COVID syndrome, participated in an examination that revealed deficits in exercise capacity, strength, breathing pattern, mild depression, emotional breakdown, and mild anxiety accompanied by "brain fog" with activity. Her primary complaint was fatigue with ordinary activities around her home that impeded her from returning to work. On examination, scores included six-minute walk test distance (6MWD): 79.5 m, UCSD Shortness of Breath Questionnaire (SOBQ): 72/120, and Patient Health Questionnaire (PHQ-9): 6/27. The patient participated in 20 biweekly sessions with a focus on patient education, supporting emotional health, aerobic training, strengthening exercises, breathing exercises, and home exercise program. OUTCOMES: At discharge, the patient's exercise capacity, muscle strength, dyspnea, and depression improved, beyond the MCID/MID values, 6MWD: 335 m, SOBQ: 34/120; and PHQ-9 :1/27. The patient had no anxiety with activity and reported confidence to resume activities, allowing her to return to work safely. CONCLUSION: Following an intervention that addressed emotional needs with physical symptoms, our patient with post-COVID fatigue showed substantial improvements in exercise capacity, muscle strength, dyspnea, and depression. This highlights the consideration of psychosocial well-being in our plan of care for this population.

The Impact of a Less Restrictive Poststernotomy Activity Protocol Compared With Standard Sternal Precautions in Patients Following Cardiac Surgery.

OBJECTIVE: Guidelines following median sternotomy typically include strict sternal precautions (SP). Recently, alternative approaches propose less functional restrictions while avoiding excessive stress to the sternum. The study aimed to determine the effect of a less restrictive (LR) approach versus a standard SP protocol after median sternotomy. METHODS: The study was a cross-sectional design (n = 364; SP: n = 172, 66.3 [SD = 11.2] years; LR: n = 196, 65.2 [SD = 11.2] years). This study ran in 2 consecutive phases and compared 2 groups after median sternotomy at a community-based hospital. The LR group received instructions on the Keep Your Move in the Tube approach. At 2 to 3 weeks after discharge, sternal instability was assessed using the Sternal Instability Scale, and patients completed a self-reported survey (perceived pain rating/frequency, sternal instability, and functional mobility). The 2 groups were compared using the Mann-Whitney U test and chi-square test (P < .05). RESULTS: There were no significant differences between the 2 groups for all the outcomes, Sternal Instability Scale, pain rating, pain frequency, perceived sternal instability, difficulty with functional mobility, length of stay, and discharge disposition. CONCLUSIONS: In our study, the implementation of the LR approach, Keep Your Move in the Tube, had no adverse effect on outcomes 2 to 3 weeks following median sternotomy. Although no statistically significant differences were noted for all outcomes, patients with the LR approach reported less difficulty with functional mobility. IMPACT STATEMENT: These data are useful in clinical decision-making regarding alternative approaches for mobility following sternotomy.

Outcomes following a locomotor training protocol on balance, gait, exercise capacity, and community integration in an individual with a traumatic brain injury: a case report.

Background and Purpose: The NeuroRecovery Network (NRN) established a locomotor training protocol that has shown promising results for individuals with spinal cord injury, yet research to date has not determined its feasibility in those with traumatic brain injury (TBI). The purpose of this case report was to determine the feasibility of implementing the NRN protocol in an individual with a TBI. Case Description: The participant was a 38-year-old male, 21 years post-TBI. Twenty-four sessions of the therapy portion of the NRN protocol were provided. Outcome measures included the Berg Balance Scale (BBS), spatial temporal parameters of gait, 6-Minute Walk Test and Community Integration Questionnaire (CIQ). Outcomes: His BBS score improved from 37/56 to 43/56. Left step length improved; although gait speed, cadence, stride length and right step length did not. Observable changes were noted in quality of gait. Six-Minute Walk Distance increased by 47.2 m while CIQ score changes did not exceed the minimal detectable change (MDC) value. Discussion: Use of the NRN protocol may be feasible in individuals with TBI, though 24 sessions may not have been enough to achieve the full potential benefit of this intervention in an individual with a chronic TBI.

Comparison of forward versus backward walking using body weight supported treadmill training in an individual with a spinal cord injury: a single subject design.

PURPOSE/HYPOTHESIS: Body weight supported treadmill training (BWSTT) is a task-specific intervention that promotes functional locomotion. There is no research evaluating the effect of backward walking (BW) using BWSTT in individuals with spinal cord injury (SCI). The purpose of this single subject design was to examine the differences between forward walking (FW) and BW training using BWSTT in an individual with quadriparesis. METHODS: The participant was a 57-year-old male with incomplete C3-C6 SCI. An ABABAB design (A = BW; B = FW; each phase = 3 weeks of biweekly sessions) was utilized. Outcome measures included: gait parameters; a timed 4-meter walk; the 5-repetition sit-to-stand test (STST); tandem stance time; and 6-minute walk test (6MWT). Data was analyzed with split level method of trend estimation. RESULTS: Improvements in gait parameters, on the timed 4-meter walk, 6MWT, tandem balance and aerobic endurance were similar with FW and BW training. The only difference between FW and BW training was that BW training resulted in greater improvements in the STST. CONCLUSIONS: The results of this study suggest that in this individual backward walking training was advantageous, resulting in improved ability to perform the 5-repetition STST. It is suspected that these changes can be attributed to the differences in muscle activation and task difficulty between FW and BW.

Comparison of measures of physical performance among young children who are healthy weight, overweight, or obese.

PURPOSE: To determine the differences in gait, balance, muscle strength, and physical activity in young children who are healthy weight (HW), overweight (OW), or obese. METHODS: Participants (n = 70; 5-9 years) were classified according to their body mass index as OW/obese (n = 29) or HW (n = 41). Data were collected on gait parameters, 1-leg stance test (OLST), handgrip strength, vertical jump (VJ) height, and physical activity. An independent t test, Mann-Whitney U test, analysis of covariance (ANCOVA), and regression analyses were carried out. RESULTS: Being OW/obese resulted in a significantly increased base of support while walking (P < .05), decreased OLST performance (P < .05), and decreased VJ height (P < .01) compared with peers of HW. CONCLUSION: These findings suggest that in young children, being OW/obese may lead to an increased base of support while walking, decreased balance, and decreased leg explosive strength.

6-Minute Walk Test Performance in Young Children who are Normal Weight and Overweight.

PURPOSE: The primary purpose of this study was to investigate 6-minute walk test (6MWT) performance in young children who were normal weight (NW) and overweight (OW). METHODS: Seventy children, 5-9 years of age, participated in this study. The 6MWT was performed on an indoor walkway. Heart rate (HR), blood pressure (BP), and oxygen saturation (SaO(2)) were measured. A self-reported physical activity questionnaire was completed by a parent/guardian. Data were analyzed with independent t tests, ANOVA, correlation analyses, and logistic regression. RESULTS: The systolic BP values were higher in the children who were OW compared with their NW peers (resting mean 104.1 (8.9) mmHg vs. 97.5 (7.8) mmHg, P < 0.05; post-6WMT: mean 118.4 (10.78) mmHg vs. 109.9 (9.1) mmHg, P < 0.05). The SaO(2) values were lower in the children who were OW compared to their NW counterparts (resting: mean 97.2 (1.1) % vs. 98.0 (1.0) %, P < 0.05; post-6WMT: mean 96.8 (1.0) % vs. 97.7 (1.0) %, P < 0.05). CONCLUSIONS: The children who were OW had higher systolic BP and lower SaO(2) levels at rest and post-6WMT. More research is needed to determine if these differences contribute to children who are OW having difficulty performing exercise.

Alterations in inorganic phosphate in mouse hindlimb muscles during limb disuse.

Muscle disuse induces a wide array of structural, biochemical, and neural adaptations in skeletal muscle, which can affect its function. We recently demonstrated in patients with an orthopedic injury that cast immobilization alters the resting P(i) content of skeletal muscle, which may contribute to loss of specific force. The goal of this study was to determine the direct effect of disuse on the basal phosphate content in skeletal muscle in an animal model, avoiding the confounding effects of injury/surgery. (31)P and (1)H MRS data were acquired from the gastrocnemius muscle of young adult mice (C57BL6 female, n = 8), at rest and during a reversible ischemia experiment, before and after 2 weeks of cast immobilization. Cast immobilization resulted in an increase in resting P(i) content (75%; p < 0.001) and the P(i) to phosphocreatine (PCr) ratio (P(i)/PCr; 80%, p < 0.001). The resting concentrations of ATP, PCr and total creatine (PCr + creatine) and the intracellular pH were not significantly different after immobilization. During ischemia (30 min), PCr concentrations decreased to 54 +/- 2% and 52 +/- 6% of the resting values in pre-immobilized and immobilized muscles, respectively, but there were no detectable differences in the rates of P(i) increase or PCr depletion (0.55 +/- 0.01 mM min(-1) and 0.52 +/- 0.03 mM min(-1) before and after immobilization, respectively; p = 0.78). At the end of ischemia, immobilized muscles had a twofold higher phosphorylation potential ([ADP][P(i)]/[ATP]) and intracellular buffering capacity (3.38 +/- 0.54 slykes vs 6.18 +/- 0.57 slykes). However, the rate of PCr resynthesis (k(PCr)) after ischemia, a measure of in vivo mitochondrial function, was significantly lower in the immobilized muscles (0.31 +/- 0.04 min(-1)) than in pre-immobilized muscles (0.43 +/- 0.04 min(-1)). In conclusion, our findings indicate that 2 weeks of cast immobilization, independent of injury-related alterations, leads to a significant increase in the resting P(i) content of mouse skeletal muscle. The increase in P(i) with muscle disuse has a significant effect on the cytosolic phosphorylation potential during transient ischemia and increases the intracellular buffering capacity of skeletal muscle.

Deficit in human muscle strength with cast immobilization: contribution of inorganic phosphate.

Metabolic factors have been proposed to explain strength deficits observed in skeletal muscle with immobilization that are not completely accounted for by changes in muscle cross-sectional area (CSA) and neural adaptations. The aim of this study was to quantify changes in the resting inorganic phosphate (Pi) concentration from the medial gastrocnemius muscle during immobilization, reloading and rehabilitation. Additionally, we assessed the contributions of CSA, muscle activation and Pi concentration to plantar flexor torque during rehabilitation following immobilization. Eight persons with a surgically stabilized ankle fracture participated. Subjects were immobilized for 6-8 weeks and subsequently participated in 10 weeks of rehabilitation. Localized (31)P-Magnetic resonance spectroscopy, magnetic resonance imaging, isometric torque and activation testing were performed on the immobilized and uninvolved limbs. At 6 weeks of immobilization, significant differences were noted between the immobilized and uninvolved limbs for the Pi concentration and the Pi/PCr ratio (P < 0.05). From 6 weeks of immobilization to 3-5 days of reloading, the increase in Pi concentration (15%, P = 0.26) and Pi/PCr (20%, P = 0.29) was not significant. During rehabilitation, the relative contributions of CSA, muscle activation and Pi concentration to plantarflexor torque were 32, 44 and 40%, respectively. Together, CSA, muscle activation and Pi concentration accounted for 76% of the variance in torque (P < 0.01). In summary, our findings suggest that immobilization, independent of reloading, leads to a significant increase in the resting Pi concentration of human skeletal muscle. Additionally, alterations in resting Pi concentration may contribute to strength deficits with immobilization not accounted for by changes in muscle CSA or neural adaptations.

Relative contributions of muscle activation and muscle size to plantarflexor torque during rehabilitation after immobilization.

Muscle atrophy is clearly related to a loss of muscle torque, but the reduction in muscle size cannot entirely account for the decrease in muscle torque. Reduced neural input to muscle has been proposed to account for much of the remaining torque deficits after disuse or immobilization. The purpose of this investigation was to assess the relative contributions of voluntary muscle activation failure and muscle atrophy to loss of plantarflexor muscle torque after immobilization. Nine subjects (ages 19-23) years with unilateral ankle malleolar fractures were treated by open reduction-internal fixation and 7 weeks of cast immobilization. Subjects participated in 10 weeks of rehabilitation that focused on both strength and endurance of the plantarflexors. Magnetic resonance imaging, isometric plantarflexor muscle torque and activation (interpolated twitch technique) measurements were performed at 0, 5, and 10 weeks of rehabilitation. Following immobilization, voluntary muscle activation (56.8 +/- 16.3%), maximal cross-sectional area (CSA) (35.3 +/- 7.6 cm(2)), and peak torque (26.2 +/- 12.7 N-m) were all significantly decreased ( p < 0.0056) compared to the uninvolved limb (98.0 +/- 2.3%, 48.0 +/- 6.8 cm(2), and 105.2 +/- 27.0 N-m, respectively). During 10 weeks of rehabilitation, muscle activation alone accounted for 56.1% of the variance in torque ( p < 0.01) and muscle CSA alone accounted for 35.5% of the variance in torque ( p < 0.01). Together, CSA and muscle activation accounted for 61.5% of the variance in torque ( p < 0.01). The greatest gains in muscle activation were made during the first 5 weeks of rehabilitation. Both increases in voluntary muscle activation and muscle hypertrophy contributed to the recovery in muscle strength following immobilization, with large gains in activation during the first 5 weeks of rehabilitation. In contrast, muscle CSA showed fairly comparable gains throughout both the early and later phase of rehabilitation.

Lower-extremity muscle cross-sectional area after incomplete spinal cord injury.

OBJECTIVES: (1) To quantify skeletal muscle size in lower-extremity muscles of people after incomplete spinal cord injury (SCI), (2) to assess differences in muscle size between involved lower limbs, (3) to determine the impact of ambulatory status (using wheelchair for community mobility vs not using a wheelchair for community mobility) on muscle size after incomplete SCI, and (4) to determine if differential atrophy occurs among individual muscles after incomplete SCI. DESIGN: Case-control study. SETTING: University research setting. PARTICIPANTS: Seventeen people with incomplete SCI and 17 age-, sex-, weight-, and height-matched noninjured controls. INTERVENTIONS: Not applicable. MAIN OUTCOME MEASURES: Maximum cross-sectional area (CSA) of individual lower-extremity muscles (soleus, medial gastrocnemius, lateral gastrocnemius, tibialis anterior, quadriceps femoris, hamstrings) as assessed by magnetic resonance imaging. RESULTS: Overall, subjects with incomplete SCI had significantly smaller (24%-31%) average muscle CSA in affected lower-extremity muscles as compared with control subjects (P<.05). Mean differences were highest in the thigh muscles ( approximately 31%) compared with the lower-leg muscles ( approximately 25%). No differences were noted between the self-reported more- and less-involved limbs within the incomplete SCI group. Dichotomizing the incomplete SCI group showed significantly lower muscle CSA values in both the wheelchair (range, 21%-39%) and nonwheelchair groups (range, 24%-38%). In addition, the wheelchair group exhibited significantly greater plantarflexor muscle atrophy compared with the dorsiflexors, with maximum atrophy in the medial gastrocnemius muscle (39%). CONCLUSIONS: Our results suggest marked and differential atrophic response of the affected lower-extremity muscles that is seemingly affected by ambulatory status in people with incomplete SCI.

Changes in inorganic phosphate and force production in human skeletal muscle after cast immobilization.

Cast immobilization is associated with decreases in muscle contractile area, specific force, and functional ability. The pathophysiological processes underlying the loss of specific force production as well as the role of metabolic alterations are not well understood. The aim of this study was to quantify changes in the resting energy-rich phosphate content and specific force production after immobilization. (31)P-magnetic resonance spectroscopy, three-dimensional magnetic resonance imaging, and isometric strength testing were performed in healthy subjects and patients with an ankle fracture after 7 wk of immobilization and during rehabilitation. Muscle biopsies were obtained in a subset of patients. After immobilization, there was a significant decrease in the specific plantar flexor torque and a significant increase in the inorganic phosphate (P(i)) concentration (P < 0.001) and the P(i)-to-phosphocreatine (PCr) ratio (P < 0.001). No significant change in the PCr content or basal pH was noted. During rehabilitation, both the P(i) content and the P(i)-to-PCr ratio decreased and specific torque increased, approaching control values after 10 wk of rehabilitation. Regression analysis showed an inverse relationship between the in vivo P(i) concentration and specific torque (r = 0.65, P < 0.01). In vitro force mechanics performed on skinned human muscle fibers demonstrated that varying the P(i) levels within the ranges observed across individuals in vivo (4-10 mM) changed force production by approximately 16%. In summary, our findings clearly depict a change in the resting energy-rich phosphate content of skeletal muscle with immobilization, which may negatively impact its force generation.

Changes in distal muscle timing may contribute to slowness during sit to stand in Parkinsons disease.

OBJECTIVE: To compare patterns of muscle activation in the lower extremity and subsequent forces during sit to stand in persons with Parkinsonism. BACKGROUND: There is an interruption of the tibialis anterior/soleus interaction during forward oriented movements in some subjects with Parkinsonism, including sit to stand. This task is a major determinant of independence and 44% of those with Parkinsonism report difficulty. METHODS: 41 subjects with Parkinsonism were asked to stand up from a bench. Peak acceleration and vertical ground reaction forces, the slopes to these peaks, and the timing of events were measured. Surface electrodes were placed on tibialis anterior and soleus. RESULTS: The slower group produced force at slower rate than the fast group. The slower group spent 64% of the time taken to stand to complete the flexion-momentum phase, and the fast group spent 56%. The slower group had a larger proportion of co-contraction trials than the other groups. CONCLUSIONS: Slower subjects took longer to perform the task due to a longer time for seat off. Deficits recruiting tibialis anterior may contribute to the decreased rate of production of the acceleration forces and the longer time required for seat off. Relevance Decreased rate of rise of force is used to identify fallers in the elderly and subjects with stroke. Decreased rates of force production may therefore assist in identifying those with Parkinsonism at risk of falls. Treatment strategies designed to facilitate tibialis anterior activation may improve the functional performance of this task.

The effect of velocity on the strategies used during gait termination.

The purpose of this study was to examine the changes that occur in gait termination (GT) as cadence increases. Five healthy volunteers walked at three cadences in time to a metronome under the following conditions: normal walking, planned stopping and unplanned stopping. Electromyography and force plate data were collected at 1000 Hz. Peak posterior ground reaction force (deceleration force) was greatest for the lead limb in unplanned stopping and, in general, deceleration force increased as cadence increased. Duration of muscle activity relative to the time to peak loading was unchanged by cadence and was always longest in the lead limb during planned stopping. As cadence increases, the signal to stop must occur earlier during stance phase if a person is to stop in the subsequent step.

Braking impulse and muscle activation during unplanned gait termination in human subjects with parkinsonism.

Persons with parkinsonism (PD) are known to have difficulty with both rapid force production and declination, and may not be able to adjust force levels during bimanual tasks in the upper extremity. We proposed that these deficits might underlie the problems experienced by those with PD when attempting to rapidly terminate locomotor activity. Rapid gait termination requires concomitant increases in braking impulse and decreases in propulsion impulse. We hypothesized that those with PD would be less able to modulate muscle activity and the associated braking impulse during gait termination. Muscular activity of soleus, tibialis anterior and gluteus medius, and braking impulse were compared between a group of subjects with PD and age and gender matched control subjects. Subjects with PD had similar patterns of muscular activation to control subjects although at dramatically reduced levels of amplitude. Consequently, PD subjects were unable to generate sufficient net braking impulse under time-critical conditions.

The interaction between leading and trailing limbs during stopping in humans.

While the initiation of gait has been well studied, the mechanisms of stopping the forward progression of the center of mass have received less attention. The purpose of this current experiment was to examine the effects of constraining cadence on how the body is brought to a stop. Lower limb electromyogram (gluteus medius, hamstrings and soleus (SOL)) and force plate data were compared between two gait conditions, walking and planned stopping, at three different cadences (100, 125 and 150% of normal cadence). As cadence increased, the onset of muscle activity prior to heel-strike decreased for all muscles except SOL. SOL activity was evident prior to heel-strike during stopping and after heel-strike during walking. As cadence increased, onset times before heel-strike were shorter in stopping and SOL became active more rapidly after heel-strike in walking. The normalized duration of muscle activity remained invariant as cadence increased. This activity was always longer under the lead limb during stopping at each cadence. This was reflected by increases in the braking forces produced by the leading limb. The rate at which force was generated was not different between gait conditions but increased with increasing cadence. Thus, subjects relied less on the trailing limb and more on the leading limb as cadence increased.