Anatomical Localization of Motor Points of the Abductor Hallucis Muscle: A Cadaveric Study

OBJECTIVE: To identify the anatomical motor points of the abductor hallucis muscle in cadavers. METHODS: Motor nerve branches to the abductor hallucis muscles were examined in eight Korean cadaver feet. The motor point was defined as the site where the intramuscular nerve penetrates the muscle belly. The reference line connects the metatarsal base of the hallux (H) to the medial tubercle of the calcaneus (C). The x coordinate was the horizontal distance from the motor point to the point where the perpendicular line from the navicular tuberosity crossed the reference line. The y coordinate was the perpendicular distance from the motor point to the navicular tuberosity. RESULTS: Most of the medial plantar nerves to the abductor hallucis muscles divide into multiple branches before entering the muscles. One, two, and three motor branches were observed in 37.5%, 37.5%, and 25% of the feet, respectively. The ratios of the main motor point from the H with respect to the H-C line were: main motor point, 68.79%±5.69%; second motor point, 73.45%±3.25%. The mean x coordinate value from the main motor point was 0.65±0.49 cm. The mean value of the y coordinate was 1.43±0.35 cm. All of the motor points of the abductor hallucis were consistently found inferior and posterior to the navicular tuberosity. CONCLUSION: This study identified accurate locations of anatomical motor points of the abductor hallucis muscle by means of cadaveric dissection, which can be helpful for electrophysiological studies in order to correctly diagnose the various neuropathies associated with tibial nerve components.

Evaluation of the neuromuscular compartments in the peroneus longus muscle through electrical stimulation and accelerometry

BACKGROUND: Muscles are innervated exclusively by a nerve branch and possess definite actions. However, mammalian skeletal muscles, such as the trapezius, the medial gastrocnemius, and the peroneus longus, are compartmentalized. In the peroneus longus muscle, multiple motor points, which innervate individual neuromuscular compartments (NMC), the superior (S-NMC), anteroinferior (AI-NMC), and posteroinferior (PI-NMC), have been described. The contribution of each neuromuscular compartment to the final action of the muscle is fundamental for the rehabilitation of patients afflicted by neurological and muscle dysfunctions. Interventions are often based on electrical principles that take advantage of the physiological characteristics of muscles and nerves to generate therapeutic effects. OBJECTIVE: To compare the effects of stimulating the different neuromuscular compartments (NMCs) of the peroneus longus muscle on the motor threshold (MT) and acceleration of the foot. METHOD: This is a cross-sectional study comprising 37 subjects. The three NMCs of the peroneus longus muscle were stimulated, and the acceleration of the foot and the motor threshold of each NMC were evaluated. A repeated measures analysis of variance with Bonferroni corrections of two intra-subjects factors was performed. RESULTS: The stimulation of the different NMCs did not result in any differences in MT (F=2.635, P=0.079). There were significant differences between the axes of acceleration caused by the stimulation of the different NMCs (F=56,233; P=0.000). The stimulation of the posteroinferior compartment resulted in the greatest acceleration in the X-axis (mean 0.614; standard deviation 0.253). CONCLUSIONS: The posteroinferior compartment primarily contributes to the eversion movement of the foot. NMCs have specific functional roles that contribute to the actions of the muscles to which they belong. .

Ubicación de la zona de inervación del músculo flexor corto del pulgar en individuos sanos de ambos sexos / Flexor pollicis brevis muscle innervation zone location in healthy individuals of both sexes

El músculo flexor corto del pulgar (FCP) se localiza en la eminencia tenar y tiene un importante rol en las funciones del dedo pulgar. Existen escasos antecedentes acerca de la distribución de las zonas de inervación (ZI) de este músculo y las posibles diferencias entre individuos de diferente sexo. El conocimiento de la localización de las ZI del FCP podría ser de ayuda en el tratamiento de la mano espástica, sirviendo para definir el sitio de inyección de la toxina botulínica. El objetivo de esta investigación fue describir las ubicaciones de las ZI del FCP usando electromiografía de superficie, y hacer una comparación entre individuos de sexo masculino y femenino. Treinta jóvenes voluntarios sanos, participaron en este estudio (15 hombres: 21.5 +/- 2.6 años, 70.7 +/- 7.2 kg y 175.0 +/- 5.5 cm. 15 Mujeres: 19.9 +/- 1.4 años, 57.9 +/- 11.1 kg y 161.9 +/- 6.6 cm). Las ZI fueron identificadas mediante la grabación de los potenciales de acción de las unidades motoras del FCP, usando un arreglo de dieciséis electrodos de superficie. Los potenciales fueron grabados durante contracciones isométricas al 10 por ciento de la contracción voluntaria máxima. Las localizaciones de las ZI fueron expresadas en forma absoluta y relativa en relación a un sistema de referencia construido en la palma de la mano, en base a referencias anatómicas. No existieron diferencias significativas en las ubicaciones de las ZI entre los participantes de sexo masculino y femenino de la muestra evaluada. Para el grupo de participantes en este estudio, las ZI del FCP se encontraron al 41.9 por ciento de la distancia comprendida entre el extremo palpable más distal y medial de la interlínea articular metacarpofalángica del pulgar y la línea que nace en el vértice palpable del extremo proximal de la primera falange del tercer dedo pasado por el pliegue longitudinal radial.

The flexor pollicis brevis (FPB) is a muscle of the thenar eminence that plays an important role in thumb function. There is data about its innervation zone (IZ) distribution and sex differences. Knowing the location of the ZI of FPB could be helpful in treating spastic hand, serving to define the site of injection of the botulinum toxin. The aim of this study was to describe the IZ location in the FPB using surface electromyography (sEMG), and also make a comparison between male and female subjects. Thirty young healthy volunteers participated in this study (15 males: 21.5 +/- 2.6 years, 70.7 +/- 7.2 kg y 175.0 +/- 5.5cm. 15 Females: 19.9 +/- 1.4 years, 57.9 +/- 11.1 kg y 161.9 +/- 6.6 cm). The IZ was identified by recording the action potentials of the FPB motor units, using a sixteen-electrode array. The action potentials were recorded during isometric contractions at 10 percent of maximum voluntary contraction. The location of the IZ was expressed as absolute and relative values in relation to a reference system constructed in the palm of the hand, based on anatomic references. There were not significant differences in the location of the IZ between male and female subjects. Of all the subjects, the IZ of the FPB was found at the 41.9 percent of the distance between the most distal and medial palpable extreme of the metacarpophalangeal joint line of the thumb and the line which rises at the palpable apex of the proximal side of the first phalanx of the third finger passing through the radial longitudinal fold.

Surface Mapping of Motor Points in Biceps Brachii Muscle

OBJECTIVE: To localize the site of motor points within human biceps brachii muscles through surface mapping using electrophysiological method. METHOD: We recorded the compound muscle action potentials of each lattice of the biceps brachii in 40 healthy subjects. Standardized reference lines were made as the following: 1) a horizontal reference line (elbow crease) and 2) a vertical reference line connecting coracoid process and mid-point of the horizontal reference line. The Compound muscle action potentials were mapped in reference to the standardized reference lines. The locations of motor points were mapped to the skin surface, in the ratio to the length of the vertical and the half of the horizontal reference lines. RESULTS: The motor point of the short head of biceps was located at 69.0+/-4.9% distal and 19.1+/-9.5% medial to the mid-point of horizontal reference line. The location of the motor point of the long head of the biceps was 67.3+/-4.3% distal and 21.4+/-8.7% lateral. The motor point of the short head of the biceps was located more medially and distally in the male subjects compared to that in the female (p<0.05). CONCLUSION: This study showed electrophysiological motor points of the biceps brachii muscles through surface mapping. This data might improve the clinical efficacy and the feasibility of motor point targeting, when injecting botulinum neurotoxin in biceps brachii.

Surface Mapping of Motor Points in Biceps Brachii Muscle

OBJECTIVE: To localize the site of motor points within human biceps brachii muscles through surface mapping using electrophysiological method. METHOD: We recorded the compound muscle action potentials of each lattice of the biceps brachii in 40 healthy subjects. Standardized reference lines were made as the following: 1) a horizontal reference line (elbow crease) and 2) a vertical reference line connecting coracoid process and mid-point of the horizontal reference line. The Compound muscle action potentials were mapped in reference to the standardized reference lines. The locations of motor points were mapped to the skin surface, in the ratio to the length of the vertical and the half of the horizontal reference lines. RESULTS: The motor point of the short head of biceps was located at 69.0+/-4.9% distal and 19.1+/-9.5% medial to the mid-point of horizontal reference line. The location of the motor point of the long head of the biceps was 67.3+/-4.3% distal and 21.4+/-8.7% lateral. The motor point of the short head of the biceps was located more medially and distally in the male subjects compared to that in the female (p<0.05). CONCLUSION: This study showed electrophysiological motor points of the biceps brachii muscles through surface mapping. This data might improve the clinical efficacy and the feasibility of motor point targeting, when injecting botulinum neurotoxin in biceps brachii.

Anatomical study of the fibularis longus muscle motor points and electrical stimulation therapy application / Estudio anatómico de los puntos motores del músculo fibularis longus y su aplicación en la terapia de electroestimulación

The fibularis longus muscle (FLM) has an important role in the movement of eversion of the foot and in maintaining the plantar arch. The electrostimulation procedures seek to maintain muscle trophism, increase strength and endurance, and are frequently used in physiotherapy, for which the clinician needs to know the location of the motor points of the FLM. Therefore, the purpose of this study was to determine the number and distribution of motor points of the FLM and relate them to observable parameters in the surface anatomy. Ten formalin-preserved limbs were used, and the lateral regions of the leg were dissected in detail. In all the cases, the muscle presented three fascicular patterns, the superior and anteroinferior fascicles presented two motor points each, while the posteroinferior fascicles were between 2 and 3 motor points. Our results suggest that there is a pattern of distribution of the superficial fibular nerve, whose knowledge is useful for clinical application in the FLM electrostimulation proceedings.

El músculo fibular largo (MFL) tiene una importante función en el movimiento de eversión del pié y en la mantención del arco plantar. Los procedimientos de electroestimulación buscan mantener el trofismo muscular, aumentar la potencia y resistencia y es frecuente su utilización en fisioterapia, para ello el clínico necesita conocer la localización de los puntos motores del MFL, por ello, el propósito de este estudio fue determinar el número y distribución de los puntos motores del MFL y relacionarlos con parámetros observables en la anatomía de superficie. Se utilizaron 10 miembros inferiores conservados y se disecó detalladamente la región lateral de la pierna. El músculo presentó en todos los casos una estructura trifascicular, los fascículos superiores y anteroinferiores presentaron dos puntos motores cada uno, mientras en el fascículo posteroinferior encontramos entre 2 y 3 puntos motores. Nuestros resultados sugieren que existe un patrón de distribución del nervio fibular superficial cuyo conocimiento es de utilidad clínica para los procedimientos de electroestimulación del MFL.

The Effect of Motor Point Block with Alcohol on Hip Adductor Muscles in Spastic Cerebral Palsy

OBJECTIVE: To investigate the effectiveness of motor point blocking using 70% alcohol for the treatment of spasticity in patients with cerebral palsy. METHOD: 16 patients with spastic cerebral palsy were injected at both hip adductor muscles with 70% alcohol. The severity of spasticity was assessed with the modified Ashworth scale (MAS) of adductor muscles, and the passive range of motion (PROM) of hip abduction. MAS and PROM were measured before, immediately after, and 1 and 3 months after the motor point block. Satisfaction of caregivers was also checked 3 months after the procedure. RESULTS: The MAS prior to the motor point block and at 3 months after the procedure were 4.44+/-0.62 and 3.63+/-1.16. The PROM before motor point block and at 3 months after the procedure were 21.81+/-14.14d egrees and 32.81+/-12.37 egrees. 11 out of 16 (68.8%) caregivers reported high satisfaction. CONCLUSION: Motor point block with 70% alcohol to the hip adductor muscles could be a safe and cost-effective procedure for relieving the localized spasticity of hip adductor muscles in spastic cerebral palsy.

Treatment of Torsion Dystonia with Motor Point Block Using Phenol : A case report

Dystonia is an abnormal movement characterized by sustained muscle contractions, frequently causing twisting and repetitive movements or abnormal postures. Torsion dystonia is characterized by torsion spasms of muscle contraction, which distorts the limbs and trunk into dystonic postures. We present a case of a patient with torsion dystonia who was recalcitrant to oral medication or even surgical operations. This patient was treated with motor point block using 5% phenol solution. Using electromyographical guidance, phenol was injected into the paraspinal and upper extremity muscles, respectively. He showed reduction of dystonia and improvement of functional abilities. Motor point block using phenol can be considered as a tool of the management for patients with torsion dystonia. MDVAQ@yumc.yonsei.ac.kr

Surface Mapping of Masseter for Botulinum Toxin Injection

Generally, many Asian women tend to dislike the square jaw, as they believe it makes the face look wider, giving a stubborn and strong impression. Contouring of the mandible is therefore a relatively common aesthetic procedure among Asians. These days, the use of botulinum toxin for contouring of the lower face offer simple alternative to surgery. Motor point, which is the site over a muscle where its contraction may be elicited by a minimal intensity short duration electrical stimulus, is the optimal injection point of botulinum toxin. Study was undertaken to identify the location of motor point of the masseter muscle and the skin surface landmark. First, the thickest point of the masseter muscle was inspected through palpation and inspection by 3 different individual plastic surgeons and then compound muscle action potentials(CMAPs) of masseter muscle in 15 health volunteers were recorded using EMG. For the localization of the measured points, line between lateral canthus to the mandibular angle was used. Location of motor points were mapped to skin surface from lateral canthus in a percentage of the distance along the landmark line and in distance in millimeters. The clinical injection point was located at 71.69 percentile and 7.3mm of the landmark line. The motor point test was located at 72.54 percentile and 7.1mm of the landmark line. The depth of motor point was 16mm. There was no statistically significant difference between the clinical injection point and the motor point. We conclude that surface mapping of motor point of the masseter muscle would increase accessibility and accuracy in botulinum toxin injection for contouring of the lower face.

Anatomical Locations of the Motor Points of the Biceps Brachii and Brachialis Muscles

OBJECTIVE: To identify the range of the precise locations of the motor points of biceps brachii and brachialis muscles in relation to bony landmarks. METHOD: Nine upper limbs of five male cadavers were dissected. The number and location of the motor points from the musculocutaneous nerve to biceps brachii and brachialis muscles were identified in relation to the bony landmarks. Bony landmarks were coracoid process and lateral epicondyle of the humerus. The length of the arm was defined as the distance from the apex of the coracoid process to the lateral epicondyle of humerus. The locations of the motor points were expressed as the percentage ratio of the length from the coracoid process to the motor points in relation to the length of the arm. RESULTS: First proximal motor points of the long head, short head of biceps brachii, and brachialis were located in 47.5 5.6%, 53.0 4.6%, 64.3 3.4% and second proximal points of them were 51.8 2.9%, 57.7 3.5%, 68.5 4.4% respectively. CONCLUSION: The identification of the locations of motor points related to the bony landmarks would increase the accuracy and ease of the motor point blocks to elbow flexors such as biceps brachii and brachialis muscles.

Anatomical Locations of the Motor Points of the Triceps Surae Muscles

OBJECTIVE: To identify the range of the precise locations of the motor points of triceps surae muscles in relation to bony landmarks. METHOD: Eight limbs of four male cadavers were dissected. The number and location of the motor points from the tibial nerve to each head of the triceps surae muscle were identified related to the bony landmarks. Bony landmarks were medial and lateral epicondyles of the femur, and medial and lateral malleolli of the tibia. The length of the lower leg was defined as the distance from the intercondylar line of the femur to the intermalleolar line of the tibia. The locations of the motor points were expressed as the vertical distance from the intercondylar line, which was normalized to the length of the lower leg. RESULTS: The most proximal motor points of the medial gastrocnemius, lateral gastrocnemius, and soleus were located in 9.6+/-3.5%, 12.0+/-3.4% and 20.5+/-3.9% of the lower leg below the intercondylar line of the femur. The most distal points were in 37.5+/-5.5%, 37.9+/-2.3% and 46.7+/-3.6%. CONCLUSION: The identification of the locations of motor points related to the bony landmarks would increase the ease and accuracy of the motor point blocks to the triceps surae muscles.

Anatomic Motor Point Localization for the Treatment of Gastrocnemius Muscle Spasticity

The location of the motor point of the gastrocnemius muscle was accurately defined relative to surrounding bony landmarks to facilitate the approach to the nerve of the gastrocnemius muscle during treatment for gastrocnemius muscle spasticity. Anatomic dissection of 40 cadaver knees was undertaken for morphometric measurement. The distances from the epicondyle of the femur to the motor branch, and from the motor branch to the motor point of the nerve to the medial head of the gastrocnemius muscle were 3.68 +/- 11.44 mm, and 37.79 +/- 7.80 mm, respectively; while those of the nerve to lateral head of the gastrocnemius muscle were 4.45 +/- 11.96 mm, and 32.16 +/- 4.64 mm, respectively. The tibial nerve lay 44.57 +/- 5.45% and 56.30 +/- 4.73% from the lateral margins of the epicondyle and the fibular head, respectively. Careful consideration of the morphometry of the motor point of the gastrocnemius muscle may provide accurate anatomical guidance, and hence reduce complications during the chemical blockage of these nerves.

Surface Mapping of Motor Points of Gastrocnemius and Soleus Muscles

OBJECTIVE: To identify the relationship between the location of motor points of gastrocnemius and soleus and the skin surface landmarks. METHOD: Compound muscle action potentials (CMAPs) of each lattice of gastrocnemius and soleus in 11 healthy subjects were recorded. Standardized reference lines were made as follows: 1) a horizontal reference line (popliteal crease) and 2) a vertical reference line drawn between mid-points of the horizontal reference line and inter-malleolus connection line. The CMAPs were mapped horizontally and vertically 1cm width to the standardized reference lines. Location of motor points was mapped to the skin surface in the ratio of length of the vertical and horizontal reference lines. RESULTS: The motor point of medial head of gastrocnemius was located at 41.0+/-6.1% distal and 54.6+/-19.2% medial to the mid-point of horizontal reference line. The location of the motor point of the lateral head of gastrocnemius was 35.7+/-5.2% distal and 48.5+/-15.1% lateral, respectively. In the soleus, the motor point was at 68.6+/-8.0% distal and 10.5+/-9.0% lateral, respectively. CONCLUSION: The motor point of the lateral head of gastrocnemius was located more proximally relative to medial head, and the motor point of soleus was located at slightly lateral side of the vertical reference line. The author concluded that mapping of motor points of the gastro-soleus muscles would increase accessibility in performing phenol motor point block or botulinum toxin injection for management of spasticity or abnormal tonicity of the ankle.

Follow-up Study of Motor Point Block by Phenol in Spastic Cerebral Palsy

OBJECTIVE: The purposes of this study are to find out the long-term effect of motor point block using phenol on spasticity and gait pattern of spastic cerebral palsy children and to examine contributing factors for success of phenol block in functional implication of cerebral palsy. METHOD: We injected 5% phenol into muscles of 35 cases with spastic cerebral palsy under the electromyographic monitoring. Pre, immediate post, and follow-up evaluations for type and severity, grade of spasticity, range of motion, and gait patterns by locomotion rating scale (LRS) were analyzed. RESULTS: The degree of spasticity was reduced dramatically by block, but this effect returned back to the level of pre-block state on follow-up evaluation. There was much improvement in pes equinus, genu recurvatum and scissoring tendency, while little change was observed in crouch gait and hind foot instability. These effects have been sustained on follow-up evaluation. The gait speed, deviation to normal gait, and instability in walking were significantly improved after block and on follow-up. Maintenance of adequate range of motion and good standing balance were the most important contributing factors determining the success in phenol block. Initial spasticity, initial and post LRS score were not significant. CONCLUSION: After phenol block, spasticity returned back to the level of pre-block state but improvement in locomotion activity was maintained over 8 months on follow-up evaluation. The maintenance of adequate range of motion and good standing balance were the most important contributing factors determining the success in motor point block for improving locomotion activity.

Effects of Intra-Articular Injection and Subscapularis Motor Point Block on Painful Hemiplegic Shoulder

OBJECTIVE: To evaluate the effects of intra-articular injection of shoulder and subscapularis motor point block on painful hemiplegic shoulder. METHOD: Thirty painful hemiplegic shoulder of recent onset stroke were divided randomly into three groups, i.e. group I: range of motion (ROM) exercise only, group II: intra-articular injection with ROM exercise, group III: subscapularis motor point block with ROM exercise. The intra-articular injection of shoulder was done with 20 ml of normal saline, 5 ml of 1% lidocaine, and 40 mg of triamcinolone. The subscapularis motor point block was done with 5 ml of 5% phenol under electromyographic guide. The ROM in external rotation and simple X-ray of shoulder in full abduction were checked in three groups at pre-treatment and post-treatment 3 week, and the glenohumeral abduction and scapulohumeral rhythm were obtained from the shoulder X-ray. RESULTS: There were significant (p<0.05) improvements of glenohumeral abduction, external rotation, and scapulohumeral rhythm of shoulder in group II and III, but improvement of only glenohumeral abduction was significant in group I. Angular increment of glenohumeral abduction and external rotation was most significant in group III compared with other two groups. CONCLUSION: These results suggest that the intra-articular injection of shoulder and subscapularis motor point block are potentially useful techniques in the prevention and management of the painful hemiplegic shoulder.

Localization of the Motor Nerve Branches and Motor Points of the Hamstring Muscles and Triceps Surae Muscle

OBJECTIVE: To identify the precise locations of the motor branches and motor points of hamstring and triceps surae muscles to the bony landmarks. METHOD: Twenty-eight limbs of 14 adult cadavers were anatomically dissected. The adult cadavers were selected randomly without regard to gender and age. The cadravers which were unable to obtain a neutral position or which received a trauma to the posterior thighs or the lower legs were excluded from the study. The number and location of the motor branches and motor points from sciatic nerve to each hamstirng muscles and from tibial nerve to each triceps surae muscles were identified related to the bony landmarks. Bony landmarks were ischial tuberosity, medial and lateral epicondyles of femur, and medial and lateral malleolli of tibia. The length of femur was defined as the distance from the ischial tuberosity to the intercondylar line of femur and the length of lower leg was defined as the distance from the intercondylar line of femur to the intermalleolar line of tibia. The locations of the muscular branches and the motor points were expressed as the percentage of the length of femur and lower leg. RESULTS: One muscular branch from the sciatic nerve to the semimembranosus muscle and from the posterior tibial nerve to the soleus muscle, and one or two muscular branches to the biceps femoris, semitendinosus, and semimembranosus, medial gastrocnemius, lateral gastrocnemius and soleus muscle were located at 23.0+/-5.7%, 21.0+/-10.5%, 25.0+/-10.3% of the femur from the ischial tuberosity and 2.0+/-6.2%, 4.0+/-3.3% and 10.0+/-3.3% of the lower leg from the intercondylar line of femur. There were one to four motor points in the hamstring and triceps surae muscles. The motor points of biceps femoris, semitendinosus and semimembranosus were located at 33.0+/-7.8%, 28.0+/-14.5% and 48.0+/-19.0% of the femur. The motor points of the medial gastrocnemius, lateral gastrocnemius and soleus were located in 5.0+/-0.6%, 10.0+/-3.0% and 18.0+/-4.3% of the lower leg below the intercondylar line of femur. CONCLUSION: The identification of the locations of muscular branches and motor points related to the bony landmarks from this study would increase the accuracy of the motor branch blocks or motor point blocks to the hamstrings and triceps surae muscles.

Motor Point Block By Phenol in Spastic Cerebral Palsy

Purpose: The purpose of this study is to find out the immediate effect of motor point block using phenol on the degree of spasticity and the gait patterns of children with spastic cerebral palsy and then to ascertain the cases to which these findings are most beneficial. Subjects & Methods: We injected 5% phenol into spastic muscles of 33 cases with spastic cerebral palsy under the electromyographic monitoring. The clinical evaluation for type and severity of cerebral palsy was performed before the block and then, observations on both the degree of spasticity using 'modified Ashworth scale' and the range of motion were made before and after the procedures. Finally, the gait patterns before and after block were analyzed by using locomotion rating scale for gait analysis. Results: The degree of spasticity, which was measured with modified Ashworth scale, was reduced dramatically through our phenol block -i. E. from 2.8 to 1.2-. The limited range of motion in some cases was not increased significantly after block. The constant pes equinus state resulted in the state that heel contact is occasionally possible. There was also much improvement in genu recurvatum and scissoring tendency, while little change was observed in crouch gait and hind foot instability. The speed of gait, deviation to normal gait and instability in walking were improved significantly after block, but their locomotion state was still moderately incomplete. When comparing the different outcomes of motor point block with one another according to the cases in moderately disabled state improved most dramatically. The group with both high degree of spasticity and the full range of motion in their joints improved by far the better after motor point block. Conclusion: The immediate effect of motor point block with phenol solution can be best described as a dramatic relief of spasticity and tip toeing, but other problems such as other abnormal gait patterns and locomotion activity or state improved little, if any. The moderately disabled children with both high degree of spasticity and the full range of motion in their joint could get the best of our findings.