The overall distribution pattern of the hand's cutaneous nerves and its clinical implications in sensory reconstruction / Patrón de distribución general de los nervios cutáneos de la mano y sus implicancias clínicas en la reconstrucción sensorial

SUMMARY: The objective of this study was to reveal the overall distribution pattern of the hand's cutaneous nerves to provide a morphological basis for the selection and matching of the hand skin for sensory reconstruction during flap transplantation. The hands of 12 adult cadavers were used for the study. Palmar region and dorsum of the hand were divided into regions I-VI. The skin of the hand containing subcutaneous fat was removed close to the muscle surface. The modified Sihler's staining method was used to visualize the overall distribution pattern of the cutaneous nerves and the areas they innervate. The median nerve, superficial branch of the ulnar nerve, and the superficial branch of the radial nerve innervated 59.27 % (containing 4.65 % of the palmar cutaneous branch of the median nerve), 36.91 %, and 3.82 % of the palm area, respectively. The superficial branch of the radial nerve, the dorsal branch of the ulnar nerve, and the median nerve innervated 45.16 %, 47.25 %, and 7.59 % of the hand's dorsal skin area, respectively. Communication was found between the arborized branches of these cutaneous nerves. Region III of the palm and region VI of the dorsum of the hand had relatively more dense nerve distribution. Except for region V, the density of the total nerve branches in each palm region was higher than that of the dorsum of the hand. The total number of nerve branches in the distal phalanx and dorsum decreased from the thumb to the digitus minimus. Our results provide morphological guidance when designing a reasonable matching flap to improve the hand's sensory function reconstruction.

RESUMEN: El objetivo de este estudio fue revelar el patrón de distribución general de los nervios cutáneos de la mano y proporcionar una base morfológica para la selección y adaptación de la piel de la mano, para la reconstrucción sensorial durante el trasplante de colgajo. Para el estudio se utilizaron 12 manos de cadáveres adultos. Las regiones palmar y dorsal se dividieron en regiones I-VI. La piel de la mano que contiene grasa subcutánea se eliminó cerca de la superficie del músculo. Para visualizar el patrón de distribución general de los nervios cutáneos y las áreas que inervan se utilizó el método de tinción de Sihler modificado. El nervio mediano, la rama superficial del nervio ulnar y la rama superficial del nervio radial inervaban el 59,27 % (que contenía el 4,65 % de la rama cutánea palmar del nervio mediano), el 36,91 % y el 3,82 % del área de la palma, respectivamente. La rama super-ficial del nervio radial, la rama dorsal del nervio ulnar y el nervio mediano inervaban el 45,16 %, el 47,25 % y el 7,59 % del área dorsal de la mano, respectivamente. Se observó comunicación entre las ramas arborizadas de estos nervios cutáneos. La región III de la palma y la región VI del dorso de la mano tenían una distribución nerviosa relativamente más densa. A excepción de la región V, la densidad de las ramas nerviosas totales en cada región de la palma fue mayor que el dorso de la mano. El número total de ramas nerviosas en la falange distal y el dorso disminuyó desde el pulgar hasta el dedo mínimo. Nuestros resultados proporcionan una guía morfológica al diseñar un colgajo compatible razonable para mejorar la reconstrucción de la función sensorial de la mano.

Whole-mount intramuscular nerve distribution pattern of medial and lateral plantar muscles and its clinical significance / 解剖学报

Objective To reveal the whole-mount distribution pattern of intramuscular nerves in the medial and lateral plantar muscles and to explore its clinical significance. Methods Twenty-four adult cadavers were dissected to remove the medial and lateral groups of the plantar muscles. The distribution pattern of the intramuscular nerves was demonstrated by modified Sihler' s staining. Results The nerve branch for adductor hallucis muscle entered the muscle from the deep surface of the insertion of the muscle, while those nerve branches for abductor hallucis, flexor hallucis brevis, abductor digiti minimi and flexor digiti minimi brevis muscles entered the muscle from the deep side of the origin of the muscle. There were one lunate and one rectangular intramuscular nerve dense regions (INDRs) in the abductor hallucis muscle; two reniform INDRs in the transverse head of the adductor hallucis muscle, one reniform and one rectangular INDRs in the oblique head of the adductor hallucis muscle; there were two rectangle INDRs in the flexor hallucis brevis, abductor digiti minimi and flexor digiti minimi brevis muscles. These five muscles were divided into two neuromuscular compartment, but the percentage position of INDR and the center of INDR on muscle length in each muscle were different. Conclusion These result may provide morphological guidance for surgical operation to avoid nerve injury, the selection and matching of muscle transplantation and the injection of botulinum toxin A to block the spasticity of these muscles.

Recommendation of the best site based on the distribution pattern of extramuscular and intramusular nerves for gluteal muscle injection / Recomendación del mejor sitio para la inyección del músculo glúteo basado en el patrón de distribución de los nervios extramusculares e intramusculares

To reveal the extra- and intramuscular nerve distribution patterns of the gluteus maximus, medius, and minimus, and to provide guidance for gluteal muscle injection in order to avoid nerve injury. Ten adult and 10 child cadavers were used. The superior and inferior gluteal nerves innervating the gluteus maximus, medius, and minimus were dissected, exposed, and sutured in-situ on the muscle. The three gluteal muscles were removed, and the distribution patterns of the intramuscular nerves were revealed by modified Sihler's nerve staining. The nerve distribution pattern was returned to the corresponding position in the body, and the patterns in the four quadrants of the buttock were analyzed. There were 3-12 extramuscular nerve branches of the gluteus maximus, medius, and minimus. After entering the muscle, these nerve branches arborized and anastomosed to form an arc-shaped, nerve-dense zone. The nerve distribution was most dense in the inferomedial region of the superolateral quadrant and the inferolateral region of the superomedial quadrant of the buttocks. The nerve distribution was relatively dense in the inferolateral region of the superolateral quadrant, and the medial region of the inferomedial quadrant. An arc-shaped, nerve-sparse zone in the superolateral and superomedial quadrants near the lower iliac crest accounted for about two-fifths of the two quadrants' limits. The arc-shaped, nerve-sparse zone in the superolateral quadrant is the preferred injection site, and the superomedial quadrant near the lower iliac crest is also recommended as a gluteal intramuscular injection region, free from nerve injury.

El objetivo de este trabajo fue revelar los patrones de distribución nerviosa extramusculat e intramuscular de los músculos glúteo máximo, medio y mínimo y proporcionar orientación para la inyección en la región glútea con el propósito de evitar lesiones nerviosas. Se utilizaron diez cadáveres adultos y diez niños. Los nervios glúteos superior e inferior que inervan a los músculos glúteo máximo, medio y mínimo fueron disecados, expuestos y suturados in situ en el músculo. Se extirparon los tres músculos glúteos y se revelaron los patrones de distribución de los nervios intramusculares mediante la tinción nerviosa de Sihler modificada. El patrón de distribución nerviosa se devolvió a la posición correspondiente en el cuerpo y se analizaron los patrones en los cuatro cuadrantes de la región glútea. Se encontraron 3 a 12 ramos nerviosos extramusculares de los músculos glúteo máximo, medio y mínimo. Después de ingresar al músculo, estas ramas nerviosas se arborizaron y anastomizaron para formar una zona densamente nerviosa en forma de arco. La distribución nerviosa fue de mayor densidad en la región inferomedial del cuadrante superolateral y en la región inferolateral del cuadrante superomedial de la región glútea. La distribución nerviosa era relativamente densa en la región inferolateral del cuadrante superolateral y en la región medial del cuadrante inferomedial. Una zona en forma de arco en los cuadrantes superolateral y superomedial y con escasa inervación, cerca de la cresta ilíaca representaba una parte de los límites de los dos cuadrantes. La zona de poca inervación en forma de arco en el cuadrante superolateral es el sitio de inyección preferido, y el cuadrante superomedial próximo a la cresta ilíaca también se recomienda como una región de inyección intramuscular glútea, libre de lesión nerviosa.

Distribución nerviosa interna del músculo temporal humano: consideraciones anatómicas y quirúrgicas / Internal nervous distribution of the human temporal muscle: anatomical and surgical considerations

Resumen Introducción: Conocer en detalle la inervación interna del músculo temporal humano permite realizar múltiples técnicas quirúrgicas y tratamientos de patologías que involucran al territorio craneofacial. Si bien en la literatura se ha descrito la inervación interna del músculo temporal humano basado en micro-disección directa, la técnica de tinción de Sihler es una herramienta ventajosa para el estudio anatómico ya que permite observar ramos nerviosos pequeños sin perder su relación tridimensional con las fibras musculares. Objetivo: Describir la distribución nerviosa al interior del músculo temporal humano en cadáveres al aplicar el método de Sihler y analizar su asociación anátomo quirúrgica. Materiales y Método: Ocho músculos temporales humanos previamente disecados fueron sometidos al método de tinción de Sihler. Cada una de las muestras se observó bajo lupa estereoscópica y transiluminación; finalmente para su descripción se dividió al músculo en tres regiones. Resultados: Se determinó la presencia de tres troncos nerviosos principales: el temporal profundo anterior, el temporal profundo medio y temporal profundo posterior, los que discurren de profundo a superficial. Además, se observaron ramos colaterales de menor calibre del nervio temporal profundo posterior que en forma de arco comunican las tres regiones del músculo. Conclusión: Se describió una distribución nerviosa interna común para los músculos estudiados en las tres dimensiones del espacio, conocimiento útil para innovar en terapias clínico-quirúrgicas del territorio craneofacial.

Introduction: Knowing in detail the inner innervation of the human temporal muscle allows to perform multiple surgical techniques and treatments of pathologies that involve the craniofacial territory. Although the internal innervation of the human temporal muscle based on direct microdissection has been described in the literature, the Sihler staining technique is an advantageous tool for anatomical study since it allows observing small nerve branches without losing its three-dimensional relationship with muscle fibers. Aim: To describe the nervous distribution within the human temporal muscle in cadavers by applying the Sihler method and analyzing its surgical anatomical association. Materials and Method: Eight previously dissected human temporal muscles were subjected to the Sihler staining method. Each one of the samples was observed under stereoscopic magnification and transillumination, finally for its description the muscle was divided into three regions. Results: The presence of three main nervous trunks was determined: the anterior deep temporal, the deep medium temporal and the posterior deep temporal, those that run from deep to superficial. In addition, collateral branches of lesser caliber of the posterior deep temporal nerve that in the form of an arc communicate the three regions of the muscle were observed. Conclusion: A common internal nervous distribution was described for the muscles studied in the three dimensions of space, useful knowledge to innovate in clinical-surgical therapies of the craniofacial territory.

Clinical and anatomical approach using Sihler's staining technique (whole mount nerve stain) / 대한해부학회지

Sihler's staining allows visualization of the nerve distribution within soft tissues without extensive dissection and does not require slide preparation, unlike traditional approaches. This technique can be applied to the mucosa, muscle, and organs that contain myelinated nerve fibers. In particular, Sihler's technique may be considered the best tool for observing nerve distribution within skeletal muscles. The intramuscular distribution pattern of nerves is difficult to observe through manual manipulation due to the gradual tapering of nerves toward the terminal end of muscles, so it should be accompanied by histological studies to establish the finer branches therein. This method provides useful information not only for anatomists but also for physiologists and clinicians. Advanced knowledge of the nerve distribution patterns will be useful for developing guidelines for clinicians who perform operations such as muscle resection, tendon transplantation, and botulinum toxin injection. Furthermore, it is a useful technique to develop neurosurgical techniques and perform electrophysiological experiments. In this review, Sihler's staining technique is described in detail, covering its history, staining protocol, advantages, disadvantages, and possible applications. The application of this technique for determining the arterial distribution pattern is also described additionally in this study.

Three Dimensional Structure of the Spinal Nerves in the Thoracolumbar Body Trunk / The Japanese Journal of Rehabilitation Medicine

The three-dimensional structure of thoracic and lumbar nerves was investigated in rats using Sihler's staining method. It was observed that the dorsal and lateral cutaneous nerves pierced the surface muscles to enter the subcutaneous tissue at a point 1-2 segments caudal to the base of the spinal nerve, while the ventral cutaneous nerves pierced the surface muscles 7 segments caudal to the base. The dorsal and lateral cutaneous nerves also ran more caudally, 2-3 and 2-4 segments, respectively, in the subcutaneous tissue. In addition, the tilt angles of spinal nerve rami lying against the transverse plane of the body trunk increased caudally, and the ventral rami showed a drastic increase in their tilt angle. Combined with our previous studies on dermatomes and sclerotomes, the present results imply that the innervation territory of the spinal nerve is shaped like a “deformed cone”, with the apex at the base of the spinal nerve and the lateral aspect expanding caudally. The stereoscopic structure of spinal nerve innervation territories may provide novel viewpoints for use in the diagnosis and treatment of disorders of the spine and spinal cord.

Study on neural and vascular distribution in triceps surae of rabbits / 第二军医大学学报

Objective:To study the neural and vascular distribution in the triceps surae of rabbits for reconstructing the muscles of motor function.Methods: Triceps surae on one side was stained with the standard method of Sihler’s nerve staining, and the blood vessels on the other side were injected with a mixture of 30% barium sulfate and gelatin, and then they were X-photographed. The resulting pictures were compared to study the intramuscular nerve and blood vessel distribution. Results: Tricep surae on the first side became transparent or semi-transparent, and its shape kept intact after being stained. The intramuscular nerve branches were clearly visualized after being stained. The muscle was divided into 3 neuromuscular compartments and Lateral gastrocnemius (LG) was subdivided into 3 subunits. The intramuscular vascular configuration on the other side was also clear on soft X-ray films. The distribution maps of the nerves and blood vessels were grossly consistent.Conclusion: Sihler’s nerve staining is able to show the original 3-dimensional picture of the intramuscular nerve branches in the triceps surae of rabbits and can be used to observe the relation between the blood vessels and nerves in the muscle in combination with intramuscular angiography. According to the neurovascular distribution, tricep surae of rabbits can be divided into different subunits (compartments) as independent function units. The design and application of the subunit as a compartment can meet the need of muscular function after transplantation.