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<article article-type="research-article" dtd-version="1.3" xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xml:lang="en"><front><journal-meta><journal-id journal-id-type="publisher-id">mes</journal-id><journal-title-group><journal-title xml:lang="en">Extreme Medicine</journal-title><trans-title-group xml:lang="ru"><trans-title>Экстремальная биомедицина</trans-title></trans-title-group></journal-title-group><issn pub-type="ppub">3033-8964</issn><issn pub-type="epub">3033-8972</issn><publisher><publisher-name>Centre for Strategic Planning of the Federal Medical and Biological Agency</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.47183/mes.2025-268</article-id><article-id custom-type="elpub" pub-id-type="custom">mes-268</article-id><article-categories><subj-group subj-group-type="heading"><subject>Research Article</subject></subj-group><subj-group subj-group-type="section-heading" xml:lang="en"><subject>CLINICAL MEDICINE</subject></subj-group><subj-group subj-group-type="section-heading" xml:lang="ru"><subject>КЛИНИЧЕСКАЯ МЕДИЦИНА</subject></subj-group></article-categories><title-group><article-title>Functional electrical stimulation for gait correction in the early recovery phase after ischemic stroke</article-title><trans-title-group xml:lang="ru"><trans-title>Функциональная электрическая стимуляция при ходьбе в раннем восстановительном периоде ишемического инсульта</trans-title></trans-title-group></title-group><contrib-group><contrib contrib-type="author" corresp="yes"><contrib-id contrib-id-type="orcid">https://orcid.org/0000-0002-2794-4912</contrib-id><name-alternatives><name name-style="eastern" xml:lang="ru"><surname>Скворцов</surname><given-names>Д. В.</given-names></name><name name-style="western" xml:lang="en"><surname>Skvortsov</surname><given-names>D. V.</given-names></name></name-alternatives><bio xml:lang="ru"><p>Скворцов Дмитрий Владимирович, д-р мед. наук, профессор</p><p>Москва</p></bio><bio xml:lang="en"><p>Dmitry V. Skvortsov, Dr. Sci. (Med.), Professor</p><p>Moscow</p></bio><email xlink:type="simple">dskvorts63@mail.ru</email><xref ref-type="aff" rid="aff-1"/></contrib><contrib contrib-type="author" corresp="yes"><contrib-id contrib-id-type="orcid">https://orcid.org/0000-0002-8441-2285</contrib-id><name-alternatives><name name-style="eastern" xml:lang="ru"><surname>Гребенкина</surname><given-names>Н. В.</given-names></name><name name-style="western" xml:lang="en"><surname>Grebenkina</surname><given-names>N. V.</given-names></name></name-alternatives><bio xml:lang="ru"><p>Гребенкина Наталья Вячеславовна</p><p>Москва</p></bio><bio xml:lang="en"><p>Natalya V. Grebenkina </p><p>Moscow</p></bio><email xlink:type="simple">grebenkina_nv@rsmu.ru</email><xref ref-type="aff" rid="aff-2"/></contrib><contrib contrib-type="author" corresp="yes"><contrib-id contrib-id-type="orcid">https://orcid.org/0000-0003-1314-3388</contrib-id><name-alternatives><name name-style="eastern" xml:lang="ru"><surname>Климов</surname><given-names>Л. В.</given-names></name><name name-style="western" xml:lang="en"><surname>Klimov</surname><given-names>L. V.</given-names></name></name-alternatives><bio xml:lang="ru"><p>Климов Леонид Владимирович, канд. мед. наук</p><p>Москва</p></bio><bio xml:lang="en"><p>Leonid V. Klimov, Cand. Sci. (Med.)</p><p>Moscow</p></bio><email xlink:type="simple">dr.klimov@mail.ru</email><xref ref-type="aff" rid="aff-3"/></contrib><contrib contrib-type="author" corresp="yes"><contrib-id contrib-id-type="orcid">https://orcid.org/0000-0001-5232-7740</contrib-id><name-alternatives><name name-style="eastern" xml:lang="ru"><surname>Кауркин</surname><given-names>С. Н.</given-names></name><name name-style="western" xml:lang="en"><surname>Kaurkin</surname><given-names>S. N.</given-names></name></name-alternatives><bio xml:lang="ru"><p>Кауркин Сергей Николаевич, канд. мед. наук, доцент</p><p>Москва</p></bio><bio xml:lang="en"><p>Sergey N. Kaurkin, Cand. Sci. (Med.) </p><p>Moscow</p></bio><email xlink:type="simple">kaurkins@bk.ru</email><xref ref-type="aff" rid="aff-4"/></contrib><contrib contrib-type="author" corresp="yes"><contrib-id contrib-id-type="orcid">https://orcid.org/0000-0002-7510-7107</contrib-id><name-alternatives><name name-style="eastern" xml:lang="ru"><surname>Булатова</surname><given-names>М. А.</given-names></name><name name-style="western" xml:lang="en"><surname>Bulatova</surname><given-names>M. A.</given-names></name></name-alternatives><bio xml:lang="ru"><p>Булатова Мария Анатольевна, канд. мед. наук</p><p>Москва</p></bio><bio xml:lang="en"><p>Mariya A. Bulatova, Cand. Sci. (Med.)</p><p>Moscow</p></bio><email xlink:type="simple">inface@mail.ru</email><xref ref-type="aff" rid="aff-4"/></contrib><contrib contrib-type="author" corresp="yes"><contrib-id contrib-id-type="orcid">https://orcid.org/0000-0003-3180-5525</contrib-id><name-alternatives><name name-style="eastern" xml:lang="ru"><surname>Иванова</surname><given-names>Г. Е.</given-names></name><name name-style="western" xml:lang="en"><surname>Ivanova</surname><given-names>G. E.</given-names></name></name-alternatives><bio xml:lang="ru"><p>Иванова Галина Евгеньевна, д-р мед. наук, профессор</p><p>Москва</p></bio><bio xml:lang="en"><p>Galina E. Ivanova, Dr. Sci. (Med.), Professor</p><p>Moscow</p></bio><email xlink:type="simple">reabilivanova@mail.ru</email><xref ref-type="aff" rid="aff-4"/></contrib></contrib-group><aff-alternatives id="aff-1"><aff xml:lang="ru"><institution>Федеральный центр мозга и нейротехнологий Федерального медико-биологического агентства; Российский национальный исследовательский медицинский университет им. Н.И. Пирогова; Федеральный научно-клинический центр специализированных видов медицинской помощи и медицинских технологий</institution><country>Россия</country></aff><aff xml:lang="en"><institution>Federal Center of Brain Research and Neurotechnologies; Pirogov Russian National Research Medical University; Federal Scientific and Clinical Center for Specialized Types of Medical Care and Medical Technologies</institution><country>Russian Federation</country></aff></aff-alternatives><aff-alternatives id="aff-2"><aff xml:lang="ru"><institution>Российский национальный исследовательский медицинский университет им. Н.И. Пирогова</institution><country>Россия</country></aff><aff xml:lang="en"><institution>Pirogov Russian National Research Medical University</institution><country>Russian Federation</country></aff></aff-alternatives><aff-alternatives id="aff-3"><aff xml:lang="ru"><institution>Федеральный центр мозга и нейротехнологий Федерального медико-биологического агентства</institution><country>Россия</country></aff><aff xml:lang="en"><institution>Federal Center of Brain Research and Neurotechnologies</institution><country>Russian Federation</country></aff></aff-alternatives><aff-alternatives id="aff-4"><aff xml:lang="ru"><institution>Федеральный центр мозга и нейротехнологий Федерального медико-биологического агентства; Российский национальный исследовательский медицинский университет им. Н.И. Пирогова</institution><country>Россия</country></aff><aff xml:lang="en"><institution>Federal Center of Brain Research and Neurotechnologies; Pirogov Russian National Research Medical University</institution><country>Russian Federation</country></aff></aff-alternatives><pub-date pub-type="collection"><year>2025</year></pub-date><pub-date pub-type="epub"><day>08</day><month>09</month><year>2025</year></pub-date><volume>27</volume><issue>3</issue><fpage>417</fpage><lpage>428</lpage><permissions><copyright-statement>Copyright &amp;#x00A9; Skvortsov D.V., Grebenkina N.V., Klimov L.V., Kaurkin S.N., Bulatova M.A., Ivanova G.E., 2025</copyright-statement><copyright-year>2025</copyright-year><copyright-holder xml:lang="ru">Скворцов Д.В., Гребенкина Н.В., Климов Л.В., Кауркин С.Н., Булатова М.А., Иванова Г.Е.</copyright-holder><copyright-holder xml:lang="en">Skvortsov D.V., Grebenkina N.V., Klimov L.V., Kaurkin S.N., Bulatova M.A., Ivanova G.E.</copyright-holder><license license-type="creative-commons-attribution" xlink:href="https://creativecommons.org/licenses/by/4.0/" xlink:type="simple"><license-p>This work is licensed under a Creative Commons Attribution 4.0 License.</license-p></license></permissions><self-uri xlink:href="https://www.extrememedicine.ru/jour/article/view/268">https://www.extrememedicine.ru/jour/article/view/268</self-uri><abstract><sec><title>Introduction</title><p>Introduction. Gait dysfunction is a complication of acute cerebrovascular accidents, which is biomechanically manifested as reduced speed and asymmetry in spatiotemporal and kinematic parameters. These impairments can be corrected using functional electrical stimulation (FES) of muscle contraction; however, the available literature primarily describes its application during the late recovery phase of stroke.</p></sec><sec><title>Objective</title><p>Objective. Evaluation of the potential of multichannel FES for gait recovery in early post-stroke rehabilitation.</p></sec><sec><title>Materials and methods</title><p>Materials and methods. The study included 11 patients (2 females and 9 males) aged 46–66 years in the early recovery period after an ischemic stroke (time since stroke onset was 69.1 ± 52.0 days) and 34 healthy subjects (18 females and 16 males) as a control group. The lower limb muscle strength and tone were assessed using the Medical Research Council Scale for Muscle Strength and the modified Ashworth scale, respectively. Gait function was evaluated using the Dynamic Gait Index, Hauser Ambulation Index, Timed-Up-and-Go test, and 10-Meter Walk test. Gait pattern function (b770), obstacle negotiation (d4551), and short-distance walking (d4500) were also examined. All patients underwent a FES therapy course (mean number of sessions — 10.8). Clinical and biomechanical examinations were performed before and after the FES therapy course. Biomechanical gait analysis was conducted using a Stadis system (Neurosoft, Russia). Statistical analysis was performed using the Statistica 12.0 software.</p></sec><sec><title>Results</title><p>Results. The conducted clinical evaluation demonstrated a minor yet statistically significant functional improvement in post-treatment testing. An increase in the scores of Dynamic Gait Index and 10-Meter Walk test was observed. A decrease in the values of Hauser Index values and the completion time of Timed- Up-and-Go test, as well as in domains (d770) and (d4500), was noted. Gait function showed improvement. The values of walking speed (p &lt; 0.05), double support time on the paretic side (p &lt; 0.05), and m. gastrocnemius activity on both the paretic and unaffected sides (p &lt; 0.05) increased.</p></sec><sec><title>Conclusions</title><p>Conclusions. The observed changes in gait function were typical of hemiparesis. During the FES therapy course, the patients showed no negative reactions. The clinical and biomechanical gait functions of patients showed minor but positive changes during the FES therapy course. Among biomechanical parameters, the amplitude of the gastrocnemius muscle course on the paretic side significantly increased, which is one of the FES target parameters. Short courses of multichannel FES can be applied in this patient category; however, their effectiveness is insufficient. Approaches to improving the FES effectiveness require further investigation.</p></sec></abstract><trans-abstract xml:lang="ru"><sec><title>Введение</title><p>Введение. Одним из осложнений острых нарушений мозгового кровообращения является нарушение функции ходьбы, которое биомеханически характеризуется снижением скорости и асимметрией пространственно-временных и кинематических параметров. Для коррекции данных изменений возможно применение функциональной электростимуляции мышц (ФЭС), однако в имеющейся литературе данный метод применяется преимущественно в позднем восстановительном периоде инсульта.</p></sec><sec><title>Цель</title><p>Цель. Оценка возможности применения многоканальной ФЭС у пациентов в раннем восстановительном периоде инсульта для восстановления функции ходьбы.</p></sec><sec><title>Материалы и методы</title><p>Материалы и методы. В исследовании приняли участие 11 пациентов (2 женщины и 9 мужчин) в возрасте от 46 до 66 лет в раннем восстановительном периоде ишемического инсульта (количество дней после инсульта составило 69,1 ± 52,0 дня) и 34 здоровых испытуемых (18 женщин и 16 мужчин) — контрольная группа. Изучали: мышечную силу нижних конечностей по Medical Research Council Weakness Scale, мышечный тонус нижних конечностей по модифицированной шкале Ашфорт; функцию ходьбы оценивали по индексу динамической походки, индексу Хаузера, тестам «Встань и иди» и десятиметровой ходьбы; а также исследовали функцию стереотипа походки (d770), преодоление препятствий (d4551) и ходьбу на короткие расстояния (d4500). Всем пациентам проведен курс ФЭС (среднее количество — 10,8 процедуры). Клиническое и биомеханическое исследования выполнены до и по окончании курса ФЭС. Биомеханическое исследование ходьбы проведено с помощью комплекса программного обеспечения «Стэдис» («Нейрософт»). Статистическая обработка данных выполнена в программе Statistica 12.0.</p></sec><sec><title>Результаты</title><p>Результаты. Клиническая оценка показала незначительное, но достоверное функциональное улучшение по результатам тестирования после проведенного лечения. Отмечено увеличение значений индекса динамической походки и теста 10-метровой ходьбы, уменьшение индекса Хаузера и времени выполнения теста «Встань и иди», а также по доменам (d770) и (d4500). Функция ходьбы улучшилась. Возросли значения скорости ходьбы (p &lt; 0,05), увеличился период двойной опоры на паретичной стороне (p &lt; 0,05), возросла активность m. gastrocnemius на паретичной и здоровой сторонах (p &lt; 0,05).</p></sec><sec><title>Выводы</title><p>Выводы. Обнаруженные изменения функции ходьбы были типичны для гемипареза. В ходе проведения курса ФЭС у пациентов не было выявлено негативных реакций на проводимую стимуляцию. Клинические и биомеханические функции ходьбы пациентов за время курса ФЭС изменилась незначительно, но динамика их положительная. Из биомеханических параметров достоверно возросла амплитуда икроножной мышцы на стороне пареза, что является одним из целевых параметров ФЭС. Проведение коротких курсов многоканальной ФЭС данной категории больных возможно, но недостаточно эффективно. Повышение эффективности ФЭС требует дальнейшего изучения.</p></sec></trans-abstract><kwd-group xml:lang="ru"><kwd>ишемический инсульт</kwd><kwd>парез</kwd><kwd>ходьба</kwd><kwd>реабилитация</kwd><kwd>электростимуляция</kwd><kwd>биомеханика ходьбы</kwd><kwd>гемиплегическая ходьба</kwd></kwd-group><kwd-group xml:lang="en"><kwd>ischemic stroke</kwd><kwd>paresis</kwd><kwd>gait</kwd><kwd>rehabilitation</kwd><kwd>electrical stimulation</kwd><kwd>gait biomechanics</kwd><kwd>hemiplegic gait</kwd></kwd-group><funding-group><funding-statement xml:lang="ru">работа выполнена в рамках НИР «Нейро Стим 2024» Рег. № ЕГИСУ НИОКТР 124031100047-5.</funding-statement><funding-statement xml:lang="en">this work was performed within the framework of the research project ‘Neuro Stim 2024’ (State Registration No. 124031100047-5 in the Unified State Information System for Research and Development).</funding-statement></funding-group></article-meta></front><body><sec><title>INTRODUCTION</title><p>Acute cerebrovascular accident (ACVA) is the second leading cause of death and one of the main causes of disability worldwide [<xref ref-type="bibr" rid="cit1">1</xref>][<xref ref-type="bibr" rid="cit2">2</xref>]. The incidence of strokes and the costs associated with necessary rehabilitation measures have been growing globally, including due to persistent health impairment experienced by a significant proportion of ACVA survivors [<xref ref-type="bibr" rid="cit3">3</xref>].</p><p>The complications of ACVA can be distinguished into motor [<xref ref-type="bibr" rid="cit4">4</xref>], cognitive [<xref ref-type="bibr" rid="cit5">5</xref>], and sensory impairments [<xref ref-type="bibr" rid="cit6">6</xref>]. One serious complication of motor disorders сonsists in an increased risk of falls [<xref ref-type="bibr" rid="cit7">7</xref>] due to dorsoflexor weakness and the appearance of foot drop in the paretic lower limb [<xref ref-type="bibr" rid="cit8">8</xref>]. A slow walking speed and asymmetry of lower limb movements are often observed, associated with reduced range of motion in the joints and the need to swing the leg sideways [<xref ref-type="bibr" rid="cit9">9</xref>][<xref ref-type="bibr" rid="cit10">10</xref>][<xref ref-type="bibr" rid="cit11">11</xref>][<xref ref-type="bibr" rid="cit12">12</xref>]. In particular, spatial asymmetry is related to step length changes [<xref ref-type="bibr" rid="cit13">13</xref>][<xref ref-type="bibr" rid="cit14">14</xref>].</p><p>Given the urgency of prompt restoration of motor functions in ACVA patients, improved rehabilitation methods are increasingly attracting the research attention. One such approach is functional electrical stimulation (FES) of muscle contraction.</p><p>Moe et al. described the FES method primarily in the context of performing a specific functional task [<xref ref-type="bibr" rid="cit15">15</xref>], particularly walking [<xref ref-type="bibr" rid="cit16">16</xref>]. A number of studies reported the effectiveness of FES in correcting typical gait changes in hemiparesis. However, the mechanism of this effect and the system for evaluating the results remain unclear. Most FES studies use changes in walking speed and muscle strength as criteria [<xref ref-type="bibr" rid="cit17">17</xref>][<xref ref-type="bibr" rid="cit18">18</xref>]. Although being clinically significant, these criteria do not provide a detailed biomechanical understanding.</p><p>The authors [<xref ref-type="bibr" rid="cit19">19</xref>] investigated the direct effects of FES on the gluteus medius and tibialis anterior muscles in post-stroke patients, including those using walking aids, and noted the importance of analyzing movements not only of the affected limb but also of the unaffected limb. Despite the findings, the researchers could not clarify the etiology of the increased step length in the unaffected limb. Another study [<xref ref-type="bibr" rid="cit20">20</xref>] demonstrated the possibility of correcting knee hyperextension and foot drop with FES; however, the authors emphasized the need for further methodological development of this approach. Unfortunately, the current literature does not address the use of FES in patients during the early recovery period after a stroke.</p><p>In this study, we set out to assess the feasibility and to evaluate the outcomes of multichannel FES applied in patients during the early recovery period after a stroke for gait function correction.</p></sec><sec><title>MATERIALS AND METHODS</title><p>The study was conducted at the Scientific Research Center for Medical Rehabilitation of the Federal Center for Brain and Neurotechnologies from April to December 2024.</p><p>The study included patients with hemiparesis in the early recovery period after a first-ever ischemic stroke (&lt; 180 days) in the middle cerebral artery territory, aged under 75 years, capable of independent ambulation (walking) without assistance, including with the use of walking aids (cane).</p><p>The exclusion criteria were cognitive impairments preventing patients from understanding instructions; sensorimotor aphasia; decompensated somatic pathology; diseases of the central and peripheral nervous system (except stroke) accompanied by neurological deficits (sequelae of trauma, tumors, polyneuropathies, etc.); orthopedic pathology (joint deformities, contractures, amputations, etc.); history of epileptic activity; skin diseases with rashes in electrode placement areas; patient refusal to participate.</p><p>Following screening, 11 patients (2 females and 9 males) aged 46 to 66 years (mean age 57.6 ± 8.0 years) were enrolled. Right-sided hemiparesis was observed in 4 participants. The mean time since stroke was 69.1 ± 52.0 days. The mean body mass index in the group was 24.9 kg/m2.</p><p>Additionally, 34 healthy participants (18 females and 16 males) were included as a control group. The mean age of participants was 29.8 years, with a mean body mass index of 20.6 kg/m2.</p></sec><sec><title>Clinical Status Assessment Methodology</title><p>For assessing the clinical status of patients, the following scales and scoring systems were used:</p><p>The following instruments were applied for gait function evaluation: Dynamic Gait Index (DGI) [<xref ref-type="bibr" rid="cit23">23</xref>], Hauser Ambulation Index [<xref ref-type="bibr" rid="cit24">24</xref>], Timed-Up-and-Go Test (TUG) [<xref ref-type="bibr" rid="cit25">25</xref>], 10 Meter Walk Test (10MWT) [<xref ref-type="bibr" rid="cit26">26</xref>].</p><p>Health impairments and patient capabilities were assessed within the “Activity and Participation” domains of the International Classification of Functioning, Disability and Health [<xref ref-type="bibr" rid="cit27">27</xref>][<xref ref-type="bibr" rid="cit28">28</xref>]: gait pattern function (b770), negotiating obstacles (d4551), short-distance walking (d4500).</p></sec><sec><title>Gait Function Assessment Methodology</title><p>Study Procedure</p><p>All patients underwent preliminary biomechanical gait analysis using a Stadis system (Neurosoft, Russia). Spatiotemporal and kinematic gait parameters were recorded using inertial sensors secured with elastic cuffs at the sacrum level and on both lower limbs: on the lateral surface of the mid-thigh, at the lateral malleolus of the ankle joint, and on the dorsal foot surface. Simultaneously, electromyographic (EMG) activity of lower limb muscles was recorded (each sensor included two EMG channels) via electrodes placed at the mid-length of:</p><p>During testing, patients walked at a self-selected pace along an 8.5-m straight path with turns at the end. Biomechanical data were recorded until 30 gait cycles had been achieved. The software automatically excluded unstable steps (turns, stumbling, acceleration/deceleration). The output included:</p><p>The first biomechanical assessment was performed for both patient and healthy control groups (baseline); the second assessment was conducted only for patients after FES therapy.</p><p>Recorded Parameters</p><p>Temporal (gait cycle [GC] in sec; others as % of GC):</p><p>Spatial:</p><p>Kinematic: angular range of motion (maximum flexion/extension, °) with temporal phase (% of GC).</p><p>Hip joint (H):</p><p>Knee joint (K):</p><p>Ankle joint (AJ):</p><p>EMG activity (peak amplitude [μV] and phase [%GC]):</p><p>Recorded goniograms and envelope EMG (muscle activation profile) parameters are illustrated in Fig. 1.</p></sec><sec><title>Functional Electrical Stimulation (FES) Methodology</title><p>For the FES procedure, we used stimulation devices from a Stedis system (Neurosoft, Russia), and FIAB stimulation electrodes (Italy). The devices were secured with the same elastic cuffs as those used for biomechanical gait analysis, positioned on: the sacrum, thighs, and external malleoli. Stimulation electrodes were applied to the muscles of the paretic limb at the upper and lower thirds of mm. quadriceps femoris, tibialis anterior, gastrocnemius and hamstring (Fig. 2).</p><p>At the next stage, the current intensity was adjusted based on two criteria: test stimulation had to produce visible muscle contraction, while the patient’s sensations had to remain below their pain threshold. The current intensity (stimulation strength) was set at the beginning of each session for each stimulated muscle. The current frequency and pulse duration parameters remained unchanged, i.e., 50 Hz and 200 ms, respectively.</p><p>After determining the current intensity, the system was calibrated and the training was initiated. Patients walked in a straight line at a self-selected pace, making turns at the end of the path and continuing to walk. Electrical pulses were delivered to the muscles at specific points in the gait cycle corresponding to the physiological peak of muscle bioelectric activity during walking in healthy individuals. Specifically:</p><p>The patient continued walking for 30 min, after which the training session ended. The procedure was stopped earlier if subjective complaints appeared (dizziness, fatigue) or at the patient’s request. Procedures were performed daily, five times per week. The course duration was determined by the patients’ hospital stay and averaged 10.8 procedures. The average procedure duration was 25.5 min.</p></sec><sec><title>Data Statistical Processing</title><p>For statistical data processing, we used the Statistica 12.0 software (StatSoft, Tulsa, USA). The normality of quantitative parameter distributions was assessed using the Shapiro–Wilk test, which showed non-normal distributions (p &lt; 0.05); therefore, all data were presented as medians with first and third quartiles Me [Q1; Q3]. To compare walking parameters in patients before and after the FES course, we used the Wilcoxon test. To compare walking parameters between the patient and control groups, we applied the Mann–Whitney U-test. A p-value &lt; 0.05 was considered statistically significant.</p><fig id="fig-1"><caption><p>Figure prepared by the authors using their own data</p><p>Fig. 1. Parameters analyzed in goniograms curves and electromyographic (EMG) muscle activity profiles: vertical scale for goniograms (hip, knee, and ankle joints) — in degrees; for muscle activity profiles (m. tibialis anterior, m. gastrocnemius, m. quadriceps femoris, hamstring) — in microvolts; horizontal scale — in percentage of the gait cycle</p></caption><graphic xlink:href="mes-27-3-g001.png"><uri content-type="original_file">https://cdn.elpub.ru/assets/journals/mes/2025/3/7bPo46L3g0g8jRq1u3YbA7jz9YCpSAzC2VhlJvrg.png</uri></graphic></fig><fig id="fig-2"><caption><p>Photo taken by the authors</p><p>Fig. 2. Placement of stimulation electrodes and devices on the patient’s lower limb: the electrodes were placed on the hemiparetic side, while the devices were attached to both legs to record biomechanical parameters during stimulation</p></caption><graphic xlink:href="mes-27-3-g002.png"><uri content-type="original_file">https://cdn.elpub.ru/assets/journals/mes/2025/3/ou0K4STQsQ6XiLNx1x4Q2O5IV3JEzyNV8CuzuWzr.png</uri></graphic></fig></sec><sec><title>RESULTS</title></sec><sec><title>Clinical parameters</title><p>The comparison of clinical characteristics in the patient group before and after the FES course revealed statistically significant changes indicating improved walking function (Table 1):</p><p>ICF (International Classification of Functioning) domains:</p></sec><sec><title>Spatial and temporal parameters</title><p>The comparison of parameters before and after the FES course revealed the following statistically significant changes (Table 2):</p><p>The comparison of pre- and post-FES parameters with control group values revealed the following statistically significant differences:</p></sec><sec><title>Kinematic parameters</title><p>The comparison of pre- and post-FES parameters revealed the following statistically significant (p &lt; 0.05) changes (Table 3):</p><p>The comparison of pre-FES patient parameters with healthy controls revealed statistically significant differences (p &lt; 0.05). Thus, the patients demonstrated reduced amplitude of initial hip flexion (Ha1) on the paretic side; earlier onset of this flexion (Hx1) on the unaffected side; decreased extension amplitude (Ha2) bilaterally with earlier phase onset (Hx2) on the paretic side and delayed onset on the unaffected side; reduced swing-phase flexion amplitude (Ha3) on the paretic side with increased amplitude on the unaffected side; and delayed onset of this flexion phase (Hx3) on the unaffected side.</p><p>In the knee joint, the analysis revealed significant kinematic alterations, i.e., reduced amplitude of first flexion (Ka1) on the paretic side accompanied by earlier onset of this flexion phase (Kx1) bilaterally; decreased extension amplitude (Ka2) with premature phase initiation (Kx2) on the paretic side; reduction in flexion amplitude (Ka3) on the paretic limb coupled with delayed flexion onset (Kx3) on the unaffected side.</p><p>In the ankle joint, earlier onset of the first extremum phase (Ax1) bilaterally and delayed initiation of full flexion (Ax2) on the unaffected side; reduced amplitude (Aa3) bilaterally with delayed phase onset (Ax3) on both sides; increased amplitude (Aa4) bilaterally and delayed initiation of its phase (Ax4) on the paretic side were noted.</p><p>The comparative analysis of kinematic parameters in post-FES patients versus healthy controls revealed the following statistically significant changes (p &lt; 0.05):</p><p>Hip joint</p><p>Knee joint</p><p>Ankle joint</p></sec><sec><title>Electromyographic parameters</title><p>The comparison of muscle bioelectrical activity profiles before and after the FES course revealed two statistically significant changes (p &lt; 0.05): an increase in the peak activity of the gastrocnemius muscle was observed for both the paretic and unaffected sides (Table 4).</p><p>The comparative analysis of pre-FES electromyographic parameters between patients and healthy controls revealed the following statistically significant differences (p &lt; 0.05):</p><p>m. tibialis anterior</p><p>m. gastrocnemius</p><p>m. quadriceps femoris</p><p>Hamstring muscles</p><p>The comparative analysis of post-FES electromyographic profiles between patients and healthy controls revealed the following statistically significant differences (p &lt; 0.05):</p><p>m. tibialis anterior:</p><p>m. gastrocnemius:</p><p>Hamstring muscles:</p><table-wrap id="table-1"><caption><p>Table 1. Clinical parameters before and after the functional electrical stimulation (FES) course</p><p>Table compiled by the authors based on their own data</p><p>Note: * — statistically significant changes, p &lt; 0.05.</p></caption><table><tbody><tr><td>Clinical Parameter</td><td>Before FES</td><td>After FES</td></tr><tr><td>Lower-extremities muscle strength, score</td><td>3</td><td>3</td></tr><tr><td>Clinical scales and tests</td></tr><tr><td>Lower-extremities muscle tone on Modified Ashworth Scale, score</td><td>1–2</td><td>1–2</td></tr><tr><td>Dynamic Gait Index</td><td>16&#13;
[ 14; 17]</td><td>19*&#13;
[ 18; 20]</td></tr><tr><td>Hauser Ambulation Index</td><td>4&#13;
[ 3; 4]</td><td>3*&#13;
[ 3; 4]</td></tr><tr><td>Timed-Up-and-Go test, s</td><td>32&#13;
[ 25; 36]</td><td>25*&#13;
[ 19; 30]</td></tr><tr><td>10-Meter Walk test, m/s</td><td>0.75&#13;
[ 0.7; 0.8]</td><td>0.9*&#13;
[ 0.85; 1]</td></tr><tr><td>ICF categories</td></tr><tr><td>b770 — gait pattern functions</td><td>2&#13;
[ 2; 3]</td><td>1*&#13;
[ 1; 2]</td></tr><tr><td>d4551 — obstacle negotiation</td><td>2&#13;
[ 1; 2]</td><td>1&#13;
[ 1; 2]</td></tr><tr><td>d4500 — short-distance walking</td><td>2&#13;
[ 1; 2]</td><td>1*&#13;
[ 0; 1]</td></tr></tbody></table></table-wrap><table-wrap id="table-2"><caption><p>Тable 2. Spatiotemporal parameters before and after the functional electrical stimulation (FES) course</p><p>Table compiled by the authors based on their own data</p><p>Note: * — significant differences versus controls, p &lt; 0.05; # — pre-post differences in ipsilateral parameters reached statistical significance, p &lt; 0.05; GC — gait cycle; ST — stance phase; SS — single support phase; DS — double support phase; BTDLS — the beginning of the terminal double limb stance phase.</p></caption><table><tbody><tr><td>Parameter</td><td>Before FES course</td><td>After FES course</td><td>Control group</td></tr><tr><td>Paretic side</td><td>Unaffected side</td><td>Paretic side</td><td>Unaffected side</td></tr><tr><td>GC, s</td><td>1.6&#13;
[ 1.5; 2]*</td><td>1.6&#13;
[ 1.4; 1.9]*</td><td>1.5&#13;
[ 1.4; 2]*</td><td>1,5&#13;
[ 1,4; 2]*</td><td>1,1&#13;
[ 1,1; 1,2]</td></tr><tr><td>ST (%)</td><td>63.3&#13;
[ 60.8; 64.5]</td><td>74.2&#13;
[ 69.1; 78]*</td><td>62.1&#13;
[ 59.9; 65]</td><td>71,8&#13;
[ 67,9; 78,2]*</td><td>63,1&#13;
[ 62,4; 64,4]</td></tr><tr><td>SS (%)</td><td>26.3&#13;
[ 22.2; 31.2]*</td><td>36.9&#13;
[ 35.9; 39.5]</td><td>27.6&#13;
[ 21.5; 31.7]*</td><td>37,8&#13;
[ 35,2; 39,7]</td><td>36,9&#13;
[ 35,7; 37,9]</td></tr><tr><td>DS (%)</td><td>34.5&#13;
[ 30.6; 43]*</td><td>34.8&#13;
[ 30.7; 42.8]*</td><td>35&#13;
[ 27.6; 40.8]* #</td><td>34,4&#13;
[ 28,2; 41,4]* #</td><td>26,1&#13;
[ 24,6; 28,1]</td></tr><tr><td>BTDLS (%)</td><td>41.6&#13;
[ 40.8; 45.8]*</td><td>57.1&#13;
[ 53.5; 60]*</td><td>42.8&#13;
[ 40; 45.6]*</td><td>56,4&#13;
[ 54,1; 60,1]*</td><td>49,9&#13;
[ 49,6; 50,3]</td></tr><tr><td>Foot clearance (cm)</td><td>8&#13;
[ 7; 12]*</td><td>13&#13;
[ 11; 15]</td><td>9&#13;
[ 7; 12]*</td><td>14&#13;
[ 11; 14]</td><td>13,5&#13;
[ 12; 15]</td></tr><tr><td>Circumduction (cm)</td><td>4&#13;
[ 3; 6]*</td><td>2&#13;
[ 2; 4]</td><td>4&#13;
[ 3; 6]*</td><td>2&#13;
[ 2; 3]</td><td>3&#13;
[ 2; 4]</td></tr><tr><td>Walking Speed (km/h)</td><td>1.7&#13;
[ 1.2; 2.5]*</td><td>2.2&#13;
[ 1.3; 2.4]*#</td><td>4.3&#13;
[ 4; 5]</td></tr></tbody></table></table-wrap><table-wrap id="table-3"><caption><p>Table 3. Kinematic parameters before and after the functional electrical stimulation (FES) course</p><p>Table compiled by the authors based on their own data</p><p>Note: * — significant differences versus controls, p &lt; 0.05; # — pre-post differences in ipsilateral parameters reached statistical significance, p &lt; 0.05; Hа1 and Hа2 — amplitude and phase of initial flexion; Hа2 and Hх2 — extension during mid-stance; Hа3 and Hх3 — flexion during swing; К0 — initial amplitude of knee; Ка1 and Кх1 — amplitude and phase of initial flexion; Ка2 and Кх2 — amplitude and phase of first extension; Ка3 and Кх3 — amplitude and phase of second flexion; A0 — initial amplitude of ankle; Aа1 and Aх1 — amplitude and phase of first dorsiflexion; Aа2 and Aх2 — amplitude and phase of first plantarflexion; Aа3 and Aх3 — amplitude and phase of second dorsiflexion; Aа4 and Aх4 — amplitude and phase of second plantarflexion.</p></caption><table><tbody><tr><td>Location</td><td>Parameter</td><td>Before FES course</td><td>After FES course</td><td>Control group</td></tr><tr><td>Paretic side</td><td>Unaffected side</td><td>Paretic side</td><td>Unaffected side</td></tr><tr><td>Hip Joint</td><td>Ha1</td><td>15*&#13;
[ 9; 16]</td><td>23&#13;
[ 19; 30]</td><td>15*&#13;
[ 10; 17]</td><td>24&#13;
[ 20; 28]</td><td>23&#13;
[ 20; 25]</td></tr><tr><td>Hx1</td><td>2&#13;
[ 1; 5]</td><td>1*&#13;
[ 1; 2]</td><td>3&#13;
[ 1; 7]</td><td>2&#13;
[ 1; 5]</td><td>2&#13;
[ 2; 3]</td></tr><tr><td>Ha2</td><td>-6*&#13;
[ -9; 1]</td><td>-6*&#13;
[ -10; -3]</td><td>-8*&#13;
[ -11; -2]</td><td>-7*#&#13;
[ -11; -3]</td><td>-11&#13;
[ -12; -9]</td></tr><tr><td>Hx2</td><td>50*&#13;
[ 47; 55]</td><td>59*&#13;
[ 56; 64]</td><td>50*&#13;
[ 47; 52]</td><td>61*&#13;
[ 57; 66]</td><td>53&#13;
[ 51; 55]</td></tr><tr><td>Ha3</td><td>16*&#13;
[ 11; 28]</td><td>31*&#13;
[ 26; 34]</td><td>17*&#13;
[ 16; 27]</td><td>31*&#13;
[ 25; 32]</td><td>24&#13;
[ 22; 27]</td></tr><tr><td>Hx3</td><td>90&#13;
[ 84; 92]</td><td>90*&#13;
[ 86; 93]</td><td>88#&#13;
[ 83; 91]</td><td>89&#13;
[ 87; 93]</td><td>87&#13;
[ 84; 89]</td></tr><tr><td>Knee Joint</td><td>K0</td><td>2&#13;
[ 0; 4]</td><td>12*&#13;
[ 8; 15]</td><td>1&#13;
[ -3; 5]</td><td>10*&#13;
[ 7; 13]</td><td>3&#13;
[ -1; 5]</td></tr><tr><td>Ka1</td><td>10*&#13;
[ 4; 12]</td><td>14&#13;
[ 14; 20]</td><td>10*&#13;
[ 3; 11]</td><td>16&#13;
[ 13; 19]</td><td>17&#13;
[ 14; 19]</td></tr><tr><td>Kx1</td><td>8*&#13;
[ 7; 10]</td><td>9*&#13;
[ 7; 12]</td><td>11*&#13;
[ 8; 13]</td><td>10#&#13;
[ 7; 15]</td><td>12&#13;
[ 12; 14]</td></tr><tr><td>Ka2</td><td>2*&#13;
[ -4; 9]</td><td>6&#13;
[ 4; 9]</td><td>-1*&#13;
[ -4; 2]</td><td>5&#13;
[ 2; 11]</td><td>6&#13;
[ 4; 9]</td></tr><tr><td>Kx2</td><td>33*&#13;
[ 31; 37]</td><td>38&#13;
[ 34; 43]</td><td>37&#13;
[ 32; 42]</td><td>38&#13;
[ 35; 40]</td><td>37&#13;
[ 34; 41]</td></tr><tr><td>Ka3</td><td>35*&#13;
[ 27; 52]</td><td>61&#13;
[ 56; 62]</td><td>37*&#13;
[ 30; 47]</td><td>61&#13;
[ 59; 64]</td><td>63&#13;
[ 60; 67]</td></tr><tr><td>Kx3</td><td>70&#13;
[ 66; 73]</td><td>79&#13;
[ 74; 83]*</td><td>71&#13;
[ 64; 73]</td><td>77*&#13;
[ 74; 81]</td><td>70&#13;
[ 69; 71]</td></tr><tr><td>Ankle Joint</td><td>A0</td><td>-9*&#13;
[ -12; -2]</td><td>-4&#13;
[ -5; -3]</td><td>-10*&#13;
[ -15; -6]</td><td>-3&#13;
[ -4; -1]</td><td>-3&#13;
[ -5; 0]</td></tr><tr><td>Aa1</td><td>-11&#13;
[ -14; -5]</td><td>-7&#13;
[ -9; -4]</td><td>-14*&#13;
[ -15; -13]</td><td>-7&#13;
[ -10; -5]</td><td>-8&#13;
[ -10; -6]</td></tr><tr><td>Ax1</td><td>4*&#13;
[ 1; 5]</td><td>4*&#13;
[ 3; 7]</td><td>3*&#13;
[ 1; 6]</td><td>6#&#13;
[ 3; 8]</td><td>7&#13;
[ 6; 8]</td></tr><tr><td>Aa2</td><td>9&#13;
[ 5; 14]</td><td>10&#13;
[ 9; 12]</td><td>8&#13;
[ 5; 12]*</td><td>13&#13;
[ 10; 14]</td><td>12&#13;
[ 10; 15]</td></tr><tr><td>Ax2</td><td>49&#13;
[ 47; 51]</td><td>58*&#13;
[ 56; 60]</td><td>48.75&#13;
[ 48; 50]</td><td>57*&#13;
[ 56; 59]</td><td>48&#13;
[ 46; 50]</td></tr><tr><td>Aa3</td><td>-5*&#13;
[ -11; -3]</td><td>-9*&#13;
[ -18; -7]</td><td>-10*&#13;
[ -13; -7]</td><td>-15* #&#13;
[ -17; -12]</td><td>-19&#13;
[ -22; -15]</td></tr><tr><td>Ax3</td><td>74*&#13;
[ 66; 79]</td><td>74*&#13;
[ 71; 80]</td><td>67*&#13;
[ 65; 76]</td><td>73*&#13;
[ 70; 77]</td><td>64&#13;
[ 63; 65]</td></tr><tr><td>Aa4</td><td>-9*&#13;
[ -11; -3]</td><td>-4*&#13;
[ -10; -4]</td><td>-9*&#13;
[ -14; -5]</td><td>-6*&#13;
[ -9; -3]</td><td>-1&#13;
[ -3; 1]</td></tr><tr><td>Ax4</td><td>94*&#13;
[ 93; 98]</td><td>82&#13;
[ 81; 98]</td><td>99*&#13;
[ 95; 100]</td><td>81&#13;
[ 81; 97]</td><td>86&#13;
[ 81; 97]</td></tr></tbody></table></table-wrap><table-wrap id="table-4"><caption><p>Table 4. Electromyographic parameters before and after functional electrical stimulation (FES)</p><p>Table compiled by the authors based on their own data</p><p>Note: * — significant differences versus controls, p &lt; 0.05; # — pre-post differences in ipsilateral parameters reached statistical significance, p &lt; 0.05; TA — m. tibalis anterior; GSC — m. gastrocnemius; QF — m. quadriceps femoris; HM — hamstrings.</p></caption><table><tbody><tr><td>Muscle</td><td>Parameter</td><td>Before FES course</td><td>After FES course</td><td>Control group</td></tr><tr><td>Paretic side</td><td>Unaffected side</td><td>Paretic side</td><td>Unaffected side</td></tr><tr><td>ТА</td><td>TAa1</td><td>72*&#13;
[ 33; 95]</td><td>163&#13;
[ 134; 230]</td><td>69*&#13;
[ 58; 135]</td><td>208*&#13;
[ 178; 278]</td><td>159&#13;
[ 118; 186]</td></tr><tr><td>TAx1</td><td>58*&#13;
[ 4; 60]</td><td>10*&#13;
[ 9; 28]</td><td>60*&#13;
[ 12; 60]</td><td>20*&#13;
[ 9; 26]</td><td>1&#13;
[ 1; 2]</td></tr><tr><td>TAa2</td><td>70*&#13;
[ 58; 104]</td><td>143&#13;
[ 118; 215]</td><td>71*&#13;
[ 60; 139]</td><td>180&#13;
[ 136; 222]</td><td>154&#13;
[ 116; 185]</td></tr><tr><td>TAx2</td><td>68*&#13;
[ 62; 97]</td><td>100&#13;
[ 84; 100]</td><td>66*&#13;
[ 64; 100]</td><td>100&#13;
[ 84; 100]</td><td>99&#13;
[ 98; 100]</td></tr><tr><td>GSС</td><td>GSСa</td><td>50*&#13;
[ 27; 81]</td><td>145&#13;
[ 133; 163]</td><td>70* #&#13;
[ 54; 96]</td><td>171#&#13;
[ 164; 208]</td><td>154&#13;
[ 113; 202]</td></tr><tr><td>GSСx</td><td>31*&#13;
[ 28; 39]</td><td>44*&#13;
[ 35; 47]</td><td>37&#13;
[ 32; 40]</td><td>39&#13;
[ 35; 47]</td><td>39&#13;
[ 37; 40]</td></tr><tr><td>QF</td><td>QFa1</td><td>62&#13;
[ 41; 67]</td><td>92*&#13;
[ 72; 109]</td><td>62&#13;
[ 52; 84]</td><td>89&#13;
[ 67; 174]</td><td>63&#13;
[ 41; 86]</td></tr><tr><td>QFx1</td><td>13*&#13;
[ 10; 17]</td><td>21*&#13;
[ 6; 24]</td><td>14&#13;
[ 6; 16]</td><td>12*&#13;
[ 9; 23]</td><td>7&#13;
[ 5; 9]</td></tr><tr><td>QFa2</td><td>40&#13;
[ 31; 58]</td><td>75&#13;
[ 60; 126]</td><td>48*&#13;
[ 40; 81]</td><td>82&#13;
[ 60; 116]</td><td>57&#13;
[ 39; 81]</td></tr><tr><td>QFx2</td><td>100&#13;
[ 51; 100]</td><td>97&#13;
[ 51; 100]</td><td>100&#13;
[ 99; 100]</td><td>95&#13;
[ 52; 100]</td><td>100&#13;
[ 99; 100]</td></tr><tr><td>HM</td><td>HMa1</td><td>53*&#13;
[ 43; 71]</td><td>108&#13;
[ 83; 146]</td><td>59*&#13;
[ 40; 79]</td><td>129*&#13;
[ 115; 146]</td><td>83&#13;
[ 62; 123]</td></tr><tr><td>HMx1</td><td>13*&#13;
[ 10; 19]</td><td>26&#13;
[ 12; 56]</td><td>14&#13;
[ 11; 25]</td><td>45&#13;
[ 31; 65]</td><td>92&#13;
[ 43; 95]</td></tr></tbody></table></table-wrap></sec><sec><title>DISCUSSION</title><p>Our study revealed minor yet characteristic gait alterations in patients with stroke-associated hemiparesis.</p><p>Following the FES therapy course, we observed:</p><p>These outcome measures (10-Meter Walk and TUG) represent the most frequently reported FES efficacy parameters in literature [29-31], with our results being consistent with existing data. However, other studies have incorporated additional clinical measures showing more variable outcomes.</p><p>The systematic review by Wang et al. covering 14 studies with 945 hemiparetic patients demonstrated FES-induced improvements in:</p><p>Conversely, an eight-week FES trial (40 min/day, 5 days/week, n=92) by Matsumoto et al. failed to show statistically significant changes in 10-Meter Walk test, Fugl-Meyer Assessment, and Timed-Up-and-Go test [<xref ref-type="bibr" rid="cit32">32</xref>].</p><p>The changes in spatiotemporal gait parameters observed in patients prior to the FES course demonstrated alterations characteristic of this post-stroke period. These included:</p><p>These biomechanical changes have been previously described [9-12] and represent typical hemiparetic gait patterns.</p><p>Following FES intervention, we observed:</p><p>As a rule, patients with hemiparesis also exhibit kinematic changes: reduced range of motion in the hip, knee, and ankle joints on the paretic side. In this case, the ankle joint is in slight extension, which reduces clearance and leads (along with other changes) to increased circumduction. The paretic side is characterized by reduced range of motion in the joints. At the same time, the healthy side is forced to compensate for the reduced activity of the paretic side. Thus, at low walking speeds, even normative kinematic parameters of the unaffected side already represent hyperfunction. The later peaks of several amplitudes on the unaffected side are the result of increased SP. The overall duration of stance phase increases, and thus the amplitude peaks also shift and occur later in time.</p><p>Following the FES course, only minor kinematic changes were observed, primarily on the unaffected side. In the available literature, FES is most commonly used for post-stroke patients with foot drop; consequently, kinematic changes are typically limited to the ankle joint. For instance, Güzel et al. described the positive effects of a four-week FES course on the ankle joint range of motion in patients during the early recovery phase after an ischemic stroke [<xref ref-type="bibr" rid="cit34">34</xref>].</p><p>The EMG analysis revealed characteristic hemiparetic changes, including reduced activity amplitudes in all analyzed muscles on the paretic side. However, less pronounced changes were noted in QF compared to other muscle groups, both in terms of amplitude and activation profile [<xref ref-type="bibr" rid="cit12">12</xref>][<xref ref-type="bibr" rid="cit35">35</xref>]. This particular muscle provides knee joint stability, and significant alterations in its activity make weight-bearing on the paretic limb impossible.</p><p>The rehabilitation course resulted in only one significant change: an increased GSC amplitude was observed bilaterally. Nevertheless, GSC activity on the paretic side remained more than two times lower than on the unaffected side, both before and after FES.</p><p>Our results demonstrate that during the early recovery period after a cerebral stroke, a three-week rehabilitation course in general and with FES application in particular objectively led to minor functional improvements. The FES training was conducted daily, with patients walking the maximum duration until fatigue. Stimulation intensity was also maintained at the maximum tolerable level for each patient. According to foreign researchers, FES courses are typically conducted over longer periods [<xref ref-type="bibr" rid="cit36">36</xref>]. However, under the conditions of our study, exceeding 10 procedures proved particularly challenging. This limitation was previously noted in our earlier research into gait restoration using biofeedback methods [<xref ref-type="bibr" rid="cit11">11</xref>][<xref ref-type="bibr" rid="cit37">37</xref>].</p><p>The duration of rehabilitation measures for patients with CNS impairments depends on their Rehabilitation Routing Scale (RRS) score, which reflects the degree of functional limitations and dependence on assistance for daily activities. According to the Program of State Guarantees for Free Medical Care, patients with RRS score 4 receive 14-day rehabilitation courses, while those with RRS score 5 receive 20-day courses. Typically, gait training begins for patients with RRS level 4 functional limitations, implying the actual length of rehabilitation between 10–12 days. Objective gait assessment is performed upon admission and before discharge.</p><p>Our findings indirectly confirm the insufficient duration of CNS rehabilitation courses within the current medical rehabilitation system and highlight the need for further investigation.</p></sec><sec><title>CONCLUSIONS</title><p>All patients included in this study demonstrated typical gait impairments associated with hemiparesis during the early recovery phase after a stroke. The administered course of multichannel FES revealed no adverse reactions. While clinical and biomechanical improvements during the FES course were modest, a statistically significant increase in gastrocnemius muscle amplitude was observed on the paretic side.</p><p>Our findings indicate that multichannel FES can be safely implemented for gait correction during early stroke recovery. 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