Archive for category Spasticity

[ARTICLE] Reinforced Feedback in Virtual Environment for Plantar Flexor Poststroke Spasticity Reduction and Gait Function Improvement – Full Text



Ankle spasticity is a frequent phenomenon that limits functionality in poststroke patients.


Our aim was to determine if there was decreased spasticity in the ankle plantar flex (PF) muscles in the plegic lower extremity (LE) and improvement of gait function in stroke patients after traditional rehabilitation (TR) in combination with virtual reality with reinforced feedback, which is termed “reinforced feedback virtual environment” (RFVE).


The evaluation, before and after treatment, of 10 hemiparetic patients was performed using the Modified Ashworth Scale (MAS), Functional Ambulatory Category (FAC), and Functional Independence Measure (FIM). The intervention consisted of 1 hour/day of TR plus 1 hour/day of RFVE (5 days/week for 3 weeks; 15 sessions in total).


The MAS and FAC reached statistical significance (P < 0.05). The changes in the FIM did not reach statistical significance (P=0.066). The analysis between the ischemic and haemorrhagic patients showed significant differences in favour of the haemorrhagic group in the FIM scale. A significant correlation between the FAC and the months after the stroke was established (P=−0.711). Indeed, patients who most increased their score on the FAC at the end of treatment were those who started the treatment earliest after stroke.


The combined treatment of TR and RFVE showed encouraging results regarding the reduction of spasticity and improvement of gait function. An early commencement of the treatment seems to be ideal, and future research should increase the sample size and assessment tools.

1. Introduction

Stroke patients suffer several deficits that affect (mildly to severely) the cognitive, psychological, or motor areas of the brain, at the expense of their quality of life []. Although rehabilitation techniques do not only act on the motor deficits [], the effects associated with the interruptions of the corticospinal tract, as well as the subsequent adaptive changes, commonly require specific interventions. Among them, the most important changes are muscle weakness, loss of dexterity, cocontraction, and increased tone and abnormal postures [].

Hemiparesis is the most common problem in poststroke patients, and its severity correlates with the functional capabilities of the individual [], being that impairment of gait function is one of the most important limitations. Furthermore, weakness of the ankle muscles caused by injury to supraspinal centres and spasticity are the most frequent phenomena that limit functionality []. The degree of spasticity of the affected ankle plantar flex (PF) muscles primarily influences gait asymmetry [], which is, in addition to depression, another independent factor for predicting falls in ambulatory stroke patients []. Physiological changes in the paretic muscles, passive or active restraint of agonist activation, and abnormal muscle activation patterns (coactivation of the opposing lower extremity (LE)) have been shown to occur after a stroke and can lead to joint stiffness (foot deformities are present in 30% of stroke patients) [], deficits in postural stabilization, and reduced muscle force generation []. To enhance this postural stability during gait, it seems that poststroke patients with impaired balance and paretic ankle muscle weakness use a compensation strategy of increased ankle muscle coactivation on the paretic side [].

Scientific evidence shows that the use of mixed techniques with different physiotherapy approaches under very broad classifications (i.e., neurophysiological, motor learning, and orthopaedic) provides significantly better results regarding recovery of autonomy, postural control, and recovery of LE in the hemiparetic patient (HP) as compared to no treatment or the use of placebo []. Within the latter techniques, we may emphasize the relearning of motor-oriented tasks [], as well as other approaches based on new technologies (e.g., treadmill [], robotics [], and functional electrical stimulation (FES) []), which are often used as additional treatments to traditional rehabilitation (TR). However, some of these emerging therapies, such as vibratory platforms [], have not been shown yet to produce as positive results as the prior ones. Thus, obtaining better results with mixed and more intensive rehabilitation treatment has been demonstrated []. Therefore, we propose to add the use of virtual reality (VR) techniques to TR to optimize results. We can use the label “VR-based therapy” because it acknowledges the VR system as the tool being used by the clinician in therapy, not as the therapy itself. It is essential to transfer the obtained gains in VR-based therapy to better functioning in the real world []. In this way, the intersection of a promising technological tool with the skills of confident and competent clinicians will more likely yield high-quality evidence and enhanced outcomes for physical rehabilitation patients [].

The application of VR to motor recovery of the hemiparetic LE (HLE) has been addressed by several authors in the last decade [], obtaining satisfactory results, in general terms, in the increase of walking speed [], cortical reorganization, balance, and kinetic-kinematic parameters. Other authors have reported improvements in the balance of patients treated with nonimmersive VR systems based on video games, using specific software and with the guidance of a therapist []. A recent study showed that VR-based eccentric training using a slow velocity is effective for improving LE muscle activity to the gastrocnemius muscle and balance in stroke []; however, the spasticity of PF muscles was not analysed in any of these studies.

Virtual reality acts as an augmented environment where feedback can be delivered in the form of enhanced information about knowledge of results and knowledge of performance (KP) []. There are systems that use this KP through the representation of trajectories during the execution of the movement, as well as visualizing these once performed, to visually check the amount of deviation from the path proposed by the physiotherapist. Several studies demonstrated that this treatment enriched by reinforced feedback in a virtual environment (RFVE) may be more effective than TR to improve the motor function of the upper limb after stroke []. In our study, the use of a VR-based system, together with a motion capture tool, allowed us to modify the artificial environment with which the patient could interact, exploiting some mechanisms of motor learning [], thus allowing greater flexibility and effective improvement in task learning. This system has been highly successful in the functional recovery of the hemiparetic upper extremity [], but its combined effect with TR on the LE has not yet reported conclusive data []. The continuous supply of feedback during voluntary movement makes it possible to continuously adjust contractile activity [], thus mitigating increments in spasticity and cocontraction processes of the patient. These settings are of great significance in motor control, and certain variables (such as the speed of the movement) can be controlled, having a direct influence on spasticity. In this line, the aim of this study is to determine if there is a decrease in the spasticity of the PF muscles and improved gait function, following a program that includes the combination of TR and VR with reinforced feedback, which is called “reinforced feedback virtual environment” (RFVE).

Moreover, as a complementary aim, we analysed the modulatory effects of demographic and clinical factors on the recovery of patients treated with TR and VR. The analysis of the influence of these modulatory variables was focused on better highlighting what type of patients would benefit most from the combined treatment of TR and VR. Particularly, we looked into the effects of age and time elapsed from the moment the stroke occurs until the patient starts neurorehabilitation. As shown in various studies, a better outcome for treatment can be expected for younger patients and for those who start the treatment earlier []. Also, comparisons were made between patients with an ischemic and haemorrhagic stroke, since differences in their recovery prognostic have been reported elsewhere, with better outcomes for the latter group [].[…]

Continue —-> Reinforced Feedback in Virtual Environment for Plantar Flexor Poststroke Spasticity Reduction and Gait Function Improvement

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Figure 2. Patient carrying out a task set out by the physiotherapist in front of the RFVE equipment.

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[Abstract] Effects of Robot-Aided Rehabilitation on Improving Ankle and Balance Performance of Stroke Survivors: A Randomized Controlled Trial


Background: Stroke survivors often experience abnormal posture control, which affects balance and locomotion. The ankle strategy is important in maintaining static balance. Prolonged spasticity may result in biomechanical changes at the ankle joint, which may cause balance disorders. The intelligent stretching device may decrease the stiffness of the ankle and improve balance. The purpose of this study was to investigate the effects of robot-aided ankle rehabilitation of stroke survivors with ankle spasticity and the correlations between biomechanical properties and balance in these patients.

Methods: Twenty inpatients post stroke with ankle spasticity performed 20 minutes of stretching treatment for 2 weeks. The study group used a rehabilitation robot to stretch the spastic ankle plantar flexors under intelligent control and the control group received manual stretching. Outcome measures included biomechanical, clinical evaluations and Pro-Kin balance test.

Results: After training, significant improvements were found in both groups in the active range of motion, muscle strength, Berg Balance Scale, Fugl-Meyer Motor Assessment of Lower Extremity, Postural Assessment Scale for Stroke Patients, 6-minute walk test, and Modified Barthel Index (P<0.05); significant decreases were found in the study group in dorsiflexion stiffness, Modified Ashworth Scale, trajectory lengths, elliptical trajectory, standard deviation medial/lateral, average speed forward/backward with eyes closed, and standard deviation forward/backward with eyes open (P=0.001, P=0.037, P=0.028, P=0.019, P=0.016, P=0.001, and P=0.033, respectively); dorsiflexion stiffness was positively correlated with the Pro-Kin balance test outcomes: ellipse area, trajectory length, average speed forward/backward, average speed medial/lateral with eyes open ( =0.352, P=0.026; =0.522, P=0.001; =0.045, P=0.004; =0.433, P=0.005, respectively); dorsiflexion stiffness was correlated with the Modified Ashworth Scale ( =0.265, P=0.041); the study group improved significantly more than the control group in the activities of daily living after training (P =0 .017).

Conclusions: The results suggested that robot-aided ankle rehabilitation had a positive effect on the biomechanical properties of the spastic ankle, and it may be feasible to improve balance post-stroke. Ankle dorsiflexion stiffness affected balance poststroke significantly; it may be a sensitive indicator for evaluating balance.

Figure 1


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[Abstract + Similar Articles] Therapeutic Effect on Post-Stroke Spastic Paralysis of Upper Extremity Treated With Combination of Kinematic-Acupuncture Therapy and Rehabilitation Training


Objective: To compare the clinical therapeutic effect on post-stroke spastic paralysis of the upper extremity between the combination of kinematic-acupuncture therapy and rehabilitation training and the combined treatment of the conventional acupuncture with rehabilitation training.

Methods: A total of 60 patients of post-stroke spastic paralysis of the upper extremity at the non-acute stage were randomized into an observation group (30 cases) and a control group (30 cases, 1 case dropped off). On the base of the routine western medication and rehabilitation treatment, the kinematic-acupuncture therapy was added in the observation group and the conventional acupuncture was used in the control group. Baihui (GV 20), Dazhui (GV 14), Jiaji (EX-B 2) from T1 to T8, Tianzong (SI 11), Jianzhen (SI 9), Jianyu (LI 15) and Quyuan (SI 13) were selected in both groups. The treatment was given once daily and the treatment for 14 days was as one course. The one course of treatment was required in this research. Separately, before treatment and in 7 and 14 days of treatment, the score of simplified Fugl-Meyer scale of the upper extremity (FMA-UE), the grade of the modified Ashworth scale (MAS) and the score of the modified Barthel index scale (MBI) were compared between the two groups.

Results: Compared before treatment, in 7 and 14 days of treatment, FMA-UE score was increased obviously in either group (P<0.01). In 14 days of treatment, FMA-UE score in the observation group was higher than that in the control group (P<0.05). In 7 and 14 days of treatment, MAS grades of shoulder joint, elbow joint, wrist joint and metacarpophalangeal joint were all improved markedly in the two groups (P<0.05). Compared with the grades in 7 days of treatment, MAS grades of elbow joint and metacarpophalangeal joint were improved markedly in 14 days of treatment in the two groups (P<0.05). Compared with the control group, MAS grades of elbow joint and metacarpophalangeal joint were improved more markedly in the observation group in 14 days of treatment (P<0.05). Compared with the score before treatment, MBI score was increased in 7 and 14 days of treatment respectively in the observation group (P<0.05, P<0.01). In 14 days of treatment, MBI score was increased in the control group (P<0.01).

Conclusion: For the patients with post-stroke spastic paralysis of the upper extremity at the non-acute stage, the combined treatment with kinematic-acupuncture therapy and rehabilitation training obviously improves the motor function of the upper extremity and the muscle tone of elbow joint and metacarpophalangeal joint. The therapeutic effect of this combination is better than that of the combined treatment of the conventional acupuncture with rehabilitation training. Additionally, this combined therapy improves the ability of daily life activity.

Keywords: acupuncture therapy,kinematic-acupuncture therapy, randomized controlled trial (RCT), spastic paralysis,stroke,upper extremity function

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via [Therapeutic Effect on Post-Stroke Spastic Paralysis of Upper Extremity Treated With Combination of Kinematic-Acupuncture Therapy and Rehabilitation Training] – PubMed

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[Abstract] Composite active range of motion (CXA) and relationship with active function in upper and lower limb spastic paresis

The aim of this study is to evaluate a novel composite measure of active range of motion (XA) and determine whether this measure correlates with active function.

Post hoc analysis of two randomized, placebo-controlled, double-blind studies with open-label extensions exploring changes in active function with abobotulinumtoxinA.

Tertiary rehabilitation centers in Australia, Europe, and the United States.

Adults with upper (n = 254) or lower (n = 345) limb spastic paresis following stroke or brain trauma.

AbobotulinumtoxinA (⩽5 treatment cycles) in the upper or lower limb.

XA was used to calculate a novel composite measure (CXA), defined as the sum of XA against elbow, wrist, and extrinsic finger flexors (upper limb) or soleus and gastrocnemius muscles (lower limb). Active function was assessed by the Modified Frenchay Scale and 10-m comfortable barefoot walking speed in the upper limb and lower limb, respectively. Correlations between CXA and active function at Weeks 4 and 12 of open-label cycles were explored.

CXA and active function were moderately correlated in the upper limb (P < 0.0001–0.0004, r = 0.476–0.636) and weakly correlated in the lower limb (P < 0.0001–0.0284, r = 0.186–0.285) at Weeks 4 and 12 of each open-label cycle. Changes in CXA and active function were weakly correlated only in the upper limb (Cycle 2 Week 12, P = 0.0160, r = 0.213; Cycle 3 Week 4, P = 0.0031, r = 0.296). Across cycles, CXA improvements peaked at Week 4, while functional improvements peaked at Week 12.

CXA is a valid measure for functional impairments in spastic paresis. CXA improvements following abobotulinumtoxinA injection correlated with and preceded active functional improvements.

via Composite active range of motion (CXA) and relationship with active function in upper and lower limb spastic paresis – Nicolas Bayle, Pascal Maisonobe, Romain Raymond, Jovita Balcaitiene, Jean-Michel Gracies,

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[ARTICLE] Functional outcome of joint mobilization added to task-oriented training on hand function in chronic stroke patients – Full Text

The Egyptian Journal of Neurology, Psychiatry and Neurosurgery Cover ImageAbstract


Approximately half of stroke patients show impaired upper limb and hand function. Task-oriented training focuses on functional tasks, while joint mobilization technique aims to restore the accessory movements of the joints.


To investigate the effect of adding joint mobilization to task-oriented training to help the patients in reaching a satisfactory level of recovery for their hand function.

Patients and methods

Thirty chronic stroke patients with paretic hand participated in the study; they were divided equally into study and control groups. The study group received joint mobilization followed by task-oriented training for the affected hand. Meanwhile, the control group received task-oriented training only. Both groups received their treatment in the form of 3 sessions per week for 6 successive weeks. The primary outcome measures were hand function that was assessed by Jebsen-Taylor hand function test (JTT) and active and passive wrist extension range of motion (ROM) that was measured by a standard goniometer. The secondary outcome measure was the grip strength of the hand that was assessed by a JAMAR adjustable hand dynamometer.


There was a significant improvement in all the outcome measurements in both groups that were more evident in the study group.


Combining joint mobilization with task-oriented training had a highly significant effect in improving the hand function in chronic stroke patients compared to task-oriented training alone.


Stroke is defined as a neurological deficit attributed to an acute vascular focal injury of the central nervous system [1]. It is a worldwide common disease that leads to serious disabilities [2]. Hemiparesis is the most common motor impairment after a stroke and frequently leads to persistent hand dysfunction [3]. Nearly about 50% of stroke patients show impaired upper limb and hand function and up to 74% rely on long-term help to perform their activities of daily living (ADL) [45]. The hand functions are complex as we use our hands in a vast variety of tasks such as grasping, pushing, holding objects, and expressing emotions [6].

Task-oriented training is a type of physiotherapy that encourages the active participation and focuses on functional tasks rather than simple repetitive training of normal motion patterns [7]. Joint mobilizations are used as an intervention to improve the range of motion (ROM), decreasing pain, and ultimately improving the upper extremity functions [8]. Joint mobilization technique proposed by Maitland is based on a graded system and is intended to restore the accessory movements of the joints by performing passive, rhythmic, and oscillatory movements [9].

After stroke, reduced ROM at joints occurs and it can be complicated by joint contractures. This occurs due to many factors such as reduced muscle length and increased stiffness of muscle and/or connective tissue. Such post stroke consequences can be solved by moving the joints through a full ROM with pressure at the end of range using the manual therapy [10]. Mobilization may help stroke patients in reducing the joint stiffness [11]. Moreover, it provides afferent input that can be used in facilitating the motor activity [1213]. Accordingly, we aimed to investigate the effect of adding joint mobilization to task-oriented training in order to help those patients in reaching a satisfactory level of recovery for their hand functions.[…]

Continue —-> Functional outcome of joint mobilization added to task-oriented training on hand function in chronic stroke patients | The Egyptian Journal of Neurology, Psychiatry and Neurosurgery | Full Text


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[VIDEO] Best Stroke Recovery Hand Exercises – Stretches For Hand Spasticity – YouTube

For more information on treating spasticity, visit… Saebo, Inc. is a medical device company primarily engaged in the discovery, development and commercialization of affordable and novel clinical solutions designed to improve mobility and function in individuals suffering from neurological and orthopedic conditions. With a vast network of Saebo-trained clinicians spanning six continents, Saebo has helped over 100,000 clients around the globe achieve a new level of independence. In 2001, two occupational therapists had one simple, but powerful goal – to provide neurological clients access to transformative and life changing products. At the time, treatment options for improving arm and hand function were limited. The technology that did exist was expensive and inaccessible for home use. With inadequate therapy options often leading to unfavorable outcomes, health professionals routinely told their clients that they have “reached a plateau” or “no further gains can be made”. The founders believed that it was not the clients who had plateaued, but rather their treatment options had plateaued. Saebo’s commitment – “No Plateau in Sight” – was inspired by this mentality; and the accessible, revolutionary solutions began. Saebo’s revolutionary product offering was based on the latest advances in rehabilitation research. From the SaeboFlex which allows clients to incorporate their hand functionally in therapy or at home, to the SaeboMAS, an unweighting device used to assist the arm during daily living tasks and exercise training, “innovation” and “affordability” can now be used in the same sentence. Over the last ten years, Saebo has grown into a leading global provider of rehabilitative products created through the unrelenting leadership and the strong network of clinicians around the world. As we celebrate our history and helping more than 100,000 clients regain function, we are growing this commitment to affordability and accessibility even further by making our newest, most innovative products more accessible than ever.

via Best Stroke Recovery Hand Exercises – Stretches For Hand Spasticity – YouTube

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[Abstract] The effectiveness of extracorporeal shock wave therapy to reduce lower limb spasticity in stroke patients: a systematic review and meta-analysis

Objective: To assess the effectiveness of Extracorporeal Shock Wave Therapy (ESWT) to reduce lower limb spasticity in adult stroke survivors.

Data Sources: A systematic review of Medline/Pubmed, CENTRAL, CINAHL, PEDro database, REHABDATA, Scielo, Scopus, Web of Science, Trip Database, and Epistemonikos from 1980 to December 2018 was carried out.

Review Methods: The bibliography was screened to identify clinical trials (controlled and before-after) that used ESWT to reduce spasticity in stroke survivors. Two reviewers independently screened references, selected relevant studies, extracted data, and assessed risk of bias by PEDro scale. The primary outcome was spasticity.

Results: A total of 12 studies (278 participants) were included (5 randomized controlled trials, 1 controlled trial, and 6 before-after studies). A meta-analysis was performed by randomized controlled trials. A beneficial effect on spasticity was found. The mean difference (MD) was 0.58; 95% confidence interval (CI) 0.30 to 0.86 and also in subgroup analysis (short, medium, and long term). The MD for range of motion was 1.81; CI −0.20 to 3.82 and for lower limb function the standard mean difference (SMD) was 0.34; 95% CI −0.09 to 0.77. Sensitivity analysis demonstrated a better beneficial effect for myotendinous junction. MD was 1.5; 95% CI −2.44 to 5.44 at long-term (9 weeks).

Conclusion: The ESWT (radial/focused) would be a good non-invasive rehabilitation strategy in chronic stroke survivors to reduce lower limb spasticity, increase ankle range of motion, and improve lower limb function. It does not show any adverse events and it is a safe and effective method.

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[Abstract] Does Casting After Botulinum Toxin Injection Improve Outcomes in Adults With Limb Spasticity? A Systematic Review – Full Text PDF


Objective: To determine current evidence for casting as an adjunct therapy following botulinum toxin injection for adult limb spasticity.

Design: The databases MEDLINE, EMBASE, CINAHL and Cochrane Central Register of Controlled Trials were searched for English language studies from 1990 to August 2018. Full-text studies using a casting protocol following botulinum toxin injection for adult participants for limb spasticity were included. Studies were graded according to Sackett’s levels of evidence, and outcome measures were categorized using domains of the International Classification of Disability, Functioning and Health. The review was prepared and reported according to PRISMA guidelines.

Results: Five studies, involving a total of 98 participants, met the inclusion criteria (2 randomized controlled trials, 1 pre-post study, 1 case series and 1 case report). Casting protocols varied widely between studies; all were on casting of the lower limbs. There is level 1b evidence that casting following botulinum toxin injection improves spasticity outcomes compared with stretching and taping, and that casting after either botulinum toxin or saline injections is better than physical therapy alone.

Conclusion: The evidence suggests that adjunct casting of the lower limbs may improve outcomes following botulinum toxin injection. Casting protocols vary widely in the literature and priority needs to be given to future studies that determine which protocol yields the best results.

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via Does Casting After Botulinum Toxin Injection Improve Outcomes in Adults With Limb Spasticity? A Systematic Review – PubMed

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[BLOG POST] Botox for Spasticity

What exactly is spasticity, and how does Botox help? If you have undergone damage to your brain or spinal cord, two parts of the body that control voluntary movement, you could potentially have a spasticity condition.

Spasticity is where certain muscles continuously contract, causing stiffness and tightness, which then disrupts speech, gait, and movements.

Symptoms of spasticity include involuntary muscle spasms, exaggeration of reflexes, unusual posture, muscle and joint stiffness, and more.

Some people experience spasticity more often during nighttime, and for some, it can be quite painful. The encounter will vary from person to person, but typically, you will feel stiff with jerky movements.

As someone with Spasticity, it is crucial to know your options for treatment, including Botox for spasticity.

What Does Botox Do For Spasticity?

Now that you understand what spasticity is, you should understand how Botox affects it. However, first, what is Botox?

Botox, otherwise known as “Botulinum toxin,” is a neurotoxic protein. In fact, it is the exact same toxin that causes “botulism” –  a life-threatening type of food poisoning. Before you get too concerned, though, you need to understand the way it is used that makes it relatively safe.

Doctors typically use Botox in small doses to treat various health problems, such as facial wrinkles and otherwise improving your looks. Because it is a toxin, your body cannot have too much at any one time, so it is used gradually in small amounts.

It paralyzes the underlying muscles to prevent conditions such as migraines, muscular disorders, and more. There are many who use it to treat their chronic migraines and headaches after a traumatic brain injury. Botox is inserted into your scalp in an effort to reduce headaches.

How does Botox for spasticity work, though?

It works by blocking the chemical signal between your nerves and muscles, which causes muscle contractions or tightening. As a result, your muscles can relax.

Botox has been found to be highly effective at providing relief from spasticity, most notably the pain and muscle stiffness that accompanies the condition.

Thousands of patients have seen safe results from using it to treat their spasticity, over the span of 25 years.

How Does It Work?

If you have a spasticity condition and are considering using Botox as a form of treatment, you should know the process behind it.

Botox for spasticity is administered directly to the affected area through an injection. The procedure usually involves multiple injections, and doctors will help minimize your discomfort as much as possible through the use of freezing sprays and oral versed. They also often encourage you to bring items from home that may bring comfort, including music.

The injections themselves are quite quick, usually only taking a few minutes, with follow-up care instructions provided afterward.

The length of time before relief occurs can vary based on several factors. However, generally, relief occurs in approximately a week and can last for about 3 months before symptoms may return.

After about three months have passed, you might begin noticing how the relieving effects of the Botox treatment gradually fade over several weeks, which is normal.

Botox might be among one of the first treatments recommended by your doctor before surgery is necessary. It’s important to remember that Botox may not be successful, though, depending on your circumstances.

In my case, I received Botox in my legs for my foot contractions. Prior to using these Botox treatments, my physical therapist attempted to cast my feet in a neutral position. However, they would not stay in place.

One week following the Botox injections, I was able to stand flat-footed for about one month before my feet retracted back into clonus. I was eventually referred to undergo tendon lengthening surgery to solve my issue.

While Botox for spasticity wasn’t successful in my case, I can understand how it relaxes the muscles to correct foot positioning, and it could be a potential solution for you.

Botox for spasticity is a recurring procedure that is often undertaken for a considerable amount of time to achieve the desired result, and it might be worthwhile considering for your spasticity condition.

The Benefits + Side Effects Of Botox For Spasticity

The benefits of using Botox for spasticity vary, again, depending on your circumstances and personal health issues. The most common benefits include:Improved gaitDecreased pain and stiffnessGreater ease when stretchingImproved range of motionDelays in the need for surgery

There are more benefits involved based on your personal experiences and goals.

Moreover, you should also know the potential side effects of using Botox for spasticity. This will help you know what to expect.Temporary general weaknessFalling (if Botox is given in lower body)Injection site painInjection site infection

These side effects will also vary from person to person.

Since spasticity is such a disruptive condition, in which it interferes with many motor activities, it’s not something you can simply ignore.

If it’s going to hinder your recovery, it needs to be addressed as soon as possible, and you should be consulting with your trusted doctor and/or physical therapist to discuss possible solutions – including Botox for spasticity.

Furthermore, if you have recently been a victim of traumatic brain injury, spasticity is one of the first health conditions you should be aware of and take action immediately before it progressively gets worse.

As always, consult a trusted physician and know all of your available options before proceeding with the desired treatment.



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[Abstract] Movement kinematics and proprioception in post-stroke spasticity: assessment using the Kinarm robotic exoskeleton – Full Text PDF



Motor impairment after stroke interferes with performance of everyday activities. Upper limb spasticity may further disrupt the movement patterns that enable optimal function; however, the specific features of these altered movement patterns, which differentiate individuals with and without spasticity, have not been fully identified. This study aimed to characterize the kinematic and proprioceptive deficits of individuals with upper limb spasticity after stroke using the Kinarm robotic exoskeleton.


Upper limb function was characterized using two tasks: Visually Guided Reaching, in which participants moved the limb from a central target to 1 of 4 or 1 of 8 outer targets when cued (measuring reaching function) and Arm Position Matching, in which participants moved the less-affected arm to mirror match the position of the affected arm (measuring proprioception), which was passively moved to 1 of 4 or 1 of 9 different positions. Comparisons were made between individuals with (n = 35) and without (n = 35) upper limb post-stroke spasticity.


Statistically significant differences in affected limb performance between groups were observed in reaching-specific measures characterizing movement time and movement speed, as well as an overall metric for the Visually Guided Reaching task. While both groups demonstrated deficits in proprioception compared to normative values, no differences were observed between groups. Modified Ashworth Scale score was significantly correlated with these same measures.


The findings indicate that individuals with spasticity experience greater deficits in temporal features of movement while reaching, but not in proprioception in comparison to individuals with post-stroke motor impairment without spasticity. Temporal features of movement can be potential targets for rehabilitation in individuals with upper limb spasticity after stroke.

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via Movement kinematics and proprioception in post-stroke spasticity: assessment using the Kinarm robotic exoskeleton – Researcher | An App For Academics

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