• Archives of Plastic Surgery
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• 제38권6호
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• pp.836-844
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• 2011

Purpose: Hands are the chief organs for physically manipulating the environment, using anywhere from the roughest motor skills to the finest, and since the fingertips contain some of the densest areas of nerve endings on the human body, they are continuously used organ with complex functions, and therefore, often gets injured. To prevent any functional loss, a detailed anatomical knowledge is required to have a perfect surgical treatment. Also it is necessary to have a thorough understanding of arrangements of the human extensor tendons and intertendinous connections when tenoplasty or tendon transfer is required. We performed a study of the arrangements of the human extensor tendons and the configuration of the intertendinous connections over the dorsum of the wrist and hand. Methods: A total of 58 hands from Korean cadavers were dissected. The arrangements of extensor indicis proprius, extensor digitorum communis, and extensor digiti minimi tendons and intertendinous connections were studied. Results: The most common distribution patterns of the extensor tendons of the fingers were as follows: a single extensor indicis proprius (EIP) tendon which inserted ulnar to the extensor digitorum-index (EDC-index); a single EDC-index; a single EDC-middle; a double EDC-ring; an absent EDC-little; a double extensor digiti minimi (EDM), a single EDC-index (98.3%), a single EDC-middle (62%), a double EDC-ring (50%), and an absent (65.5%) or a single (32.8%) EDC-little. A double (70.6%) EDM tendons were seen. Intertendinous connections were classified into 3 types: type 1 with thin filamentous type, type 2 with a thick filamentous type, and type 3 with a tendinous type subdivided to r shaped 3r type and y shaped 3y type. The most common patterns were type 1 in the 2nd intermetacarpal space, type 2 in the 3rd intermetacarpal space, and type 3r in the 4th intermetacarpal space. And in the present study, we observed one case of the extensor digitorum brevis manus (EDBM) on the boht side. Conclusion: A knowledge of both the usual and possible variations of the extensor tendon and the intertendinous connection is useful in the identification and repair of these structures.

• Archives of Plastic Surgery
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• 제50권2호
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• pp.177-181
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• 2023

Digital extensor hypoplasia (DEH) is a rare malformation that presents with loss of active finger extension at the metacarpophalangeal (MCP) joints. Descriptions of optimal treatment and outcomes in this population are sparse. We describe successful operative treatment of a child with DEH involving the extensor digitorum communis, extensor digiti minimi, and the extensor indicis proprius tendons. The 5-year-old male patient was referred for severe limitation on bilateral finger extension since birth. He had been previously diagnosed with arthrogryposis and managed conservatively. Due to lack of improvement, magnetic resonance imaging was done evidencing hypoplasia/aplasia of the extensor tendons. The patient underwent successful tendon transfers using extensor carpi radialis longus to the common extensor tendons, and one hand required an additional tenolysis procedure. 2 years postoperatively, his MCP position and finger extension are markedly improved, and he is able to grip objects without limitation or difficulty. The patient returned to full activity without restriction.

• 혜화의학회지
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• 제14권1호
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• pp.67-81
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• 2005

We have conclusions after the study of muscular system about small intestine channel of hand taiyang muscle. Judging from many studies of interrelation between Meridian muscle and muscle, it is considered that Meridian muscle theory has some similarities with modern anatomical muscular system. It is considered that Small intestine channel of hand taiyang muscle contains Flexor digitorum profundus muscle, Extensor digiti minimi muscle, Abductor digiti minimi muscle, Extensor carpi ulnaris muscle, Flexor carpi ulnaris muscle, Triceps brachii muscle, Infraspinatus muscle, Levator scapulae muscle, Sternocleidomastoid muscle, Masseter muscle, Temporalis muscle. The symptoms of small intestine channel of hand taiyang muscle is similar to referred pain of modern Myofascial Pain Syndrome, and the medical treatment of "I Tong Wi Su(以痛爲輸)" is also similar to that of Myofascial Pain Syndrome. Small intestine channel of hand taiyang muscle is one of the three yang channels of hand muscle, and it has unity in extension of upper limb and trunk in the movement. And it is thought that weakness of small intestine channel of hand taiyang muscle is related with muscular system causing Round Shoulder and Head Forward Position.

• 대한약침학회지
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• 제12권2호
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• pp.21-29
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• 2009

Objective : This study was carried to identify the anatomical component of FTMM(Foot Taeyang Meridian Muscle) in human lower limb, and further to help the accurate application to real acupuncture. Methods : FTM at the surface of the lower limb was labelled with latex. And cadaver was stripped off to demonstrate muscles, nerves and the others and to display the internal structures of FTMM, being divided into outer, middle, and inner layer. Results : FTMM in human lower limb is composed of muscles, nerves, ligaments etc. The internal composition of the FTMM in human lower limb are as follows : 1) Muscle : Gluteus maximus. biceps femoris, semitendinosus, gastrocnemius, triceps calf, fibularis brevis tendon, superior peroneal retinacula, calcaneofibular ligament, inferior extensor retinaculum, abductor digiti minimi, sheath of flexor tendon at outer layer, biceps femoris, semimembranosus, plantaris, soleus, posterior tibialis, fibularis brevis, extensor digitorum brevis, flexor digiti minimi at middle layer, and for the last time semimembranosus, adductor magnus, plantaris, popliteus, posterior tibialis, flexor hallucis longus, dorsal calcaneocuboidal ligament at inner layer. 2) Nerve : Inferior cluneal nerve, posterior femoral cutaneous n., sural cutaneous n., proper plantar branch of lateral plantar n. at outer layer, sciatic nerve, common peroneal n., medial sural cutaneous n., tibial n. at middle layer, and for the last time tibial nerve, flexor hallucis longus branch of tibial n. at inner layer. Conclusions : This study proves comparative differences from already established studies from the viewpoint of constituent elements of FTMM in the lower limb, and also in the aspect of substantial assay method. We can guess that there are conceptional differences between terms (that is, nerves which control muscles of FTMM and those which pass near by FTMM) in human anatomy.

• 대한전기학회:학술대회논문집
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• 대한전기학회 2008년도 학술대회 논문집 정보 및 제어부문
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• pp.480-481
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• 2008

본 논문은 U-Health 장치 인터페이싱을 위하여 표면 근전도를 이용한 손동작 특징들의 모델링 알고리즘에 대하여 제안하였다. 지금까지 연구에서는 표면 근전도를 측정하기 위하여 전완의 여러 부위에서 신호를 측정하였지만 휴대용 U-Health 장치들의 특성상 센서를 부착 할 수 있는 공간이 한정 되어있기 때문에 한 채널당 손동작의 인식률이 높아야하고 착용하기 편한 위치예서 신호를 측정해야 한다. 따라서 본 논문에서는 손목 근처의 수지신근(finger extensor)과 소지신근(extensor digiti minimi) 사이에 생체신호 센서를 부착하는 것을 제안했으며, 적은 수의 센서에서도 손동작에 따른 충분한 근전도 패턴을 구분해 내기 위하여 3차원 공간상에서 시간과 스케일 정보를 분석할 수 있는 다해상도 웨이블릿을 이용하였다. 정밀한 근전도 분석을 위하여 모 웨이블릿을 신경 신호의 활동전위(action potential)와 가장 유사한 형태를 가지고 있는 Daubechies 4 (db4)로 선택하였고, 이렇게 웨이블릿 분석을 통하여 1차원 신호를 16레벨로 나누어 각 신호에 대하여 에너지를 200 ms 간격으로 평가함으로서 7가지 손동작 인식을 위한 패턴 모델을 구하였다.

• 대한한의학회지
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• 제39권4호
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• pp.121-125
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• 2018

Objectives: This study was carried out to analyse Hand Greater Yang Skin in human. Methods: Hand Greater Yang meridian was labeled with latex in the body surface of the cadaver. And subsequently body among superficial fascia and muscular layer were dissected in order to observe internal structures. Results : A depth of Skin encompasses a common integument and a immediately below superficial fascia, this study established Skin boundary with adjacent structures such as relative muscle, tendon as compass. The Skin area of the Hand Greater Yang in human are as follows: The skin close to 0.1chon ulnad of $5^{th}$ nail angle, ulnad base of $5^{th}$ phalanx, ulnad head of $5^{th}$ metacapus(relevant muscle: abductor digiti minimi muscle), ulnad of hamate, tip of ulnar styloid process(extensor carpi ulnaris tendon), radiad of ulnar styloid process, 2cm below midpoint between Sohae and Yanggok(extensor carpi ulnaris), between medial epicondyle of humerus and olecranon of ulnar(ulnar nerve), The skin close to deltoid muscle, trapezius muscle, platysma muscle, inner muscles such as teres major muscle, infraspinatus muscle, supraspinatus muscle, levator scapulae muscle, splenius cervicis muscle, splenius capitis muscle, sternocleidomastoid muscle, digastric muscle, stylohyoid muscle, zygomaticus major muscle, auricularis anterior muscle. Conclusions: The Skin area of the Hand Greater Yang from the anatomical viewpoint seems to be the skin area outside the superficial fascia or muscles involved in the pathway of Hand Greater Yang meridian, collateral meridian, meridian muscle, with the condition that we consider adjacent skins.

• Korean Journal of Acupuncture
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• 제25권2호
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• pp.1-32
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• 2008

Objectives : This study was performed to understand the interrelation between 'Foot three yang meridian-muscle' and 'muscular system'. Methods : We have researched some of the literatures on Meridian-muscle theory, anatomical muscular system, myofascial pain syndrome and anatomy trains. And especially we have compared myofascial pain syndrome to anatomy trains and researched what kind of relationship is exist between them. Results : It is considered that Foot taeyang meridian-muscle includes Abductor digiti minimi m., Gastrocnemius m., Biceps femoris m., Longissimus m., Omohyoid m., Occipital m., Frontal m., Orbicularis oculi m., Trapezius m., Sternocleidomastoid m., Sternohyoid m., Zygomaticus m. Foot soyang meridian-muscle includes Dorsal interosseus m., Tendon of extensor digitorum longus m., Extensor digitorum longus m., Iliotibial band, Vastus lateralis m., Piriformis m., Tensor fasciae latae m., Internal abdominal oblique m., External abdominal oblique m,, Internal intercostal m., External intercostal m., Pectoralis major m., Sternocleidomastoid m., Posterior auricular m., Temporal m., Masseter m., Orbicularis oculi m. Foot yangmyung meridian-muscle includes Extensor digitorum longus m., Vastus lateralis m., Iliotibial band, Iliopsoas m., Anterior tibial m., Rectus femoris m., Sartorius m., Rectus abdominis m., Pectoralis major m., Internal intercostal m., External intercostal m., Sternocleidomastoid m., Masseter m., Levator labii superioris m., Zygomatic major m., Zygomatic minor m., Orbicularis oculi m., Buccinator m. and the symptoms of Foot three yang meridian-muscle are similar to the myofascial pain syndrome. Superficial back line in anatomy trains is similar to the pathway of Foot taeyang meridian-muscle. Lateral Line in anatomy trains is similar to the pathway of Foot soyang meridian-muscle. Superficial Front Arm Line in anatomy trains is similar to the pathway of Foot yangmyung meridian-muscle. Conclusions : There is some difference between myofascial pain syndrome and meridian-muscle theory in that the former explains each muscle individually, while the latter classifies muscular system in the view of integrated organism. More studies are needed in anatomy and physiology to support the integration of muscular system of Foot three yang meridian-muscle in aspect of anatomy trains.

• 대한한의학회지
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• 제26권1호
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• pp.11-17
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• 2005

This study was carried out to identify the components of the human heart meridian muscle, the regional muscle group being divided into outer, middle, and inner layers. The inner parts of the body surface were opened widely to demonstrate muscles, nerves, blood vessels and to expose the inner structure of the heart meridian muscle in the order of layers. We obtained the following results; $\cdot$ The heart meridian muscle is composed of muscles, nerves and blood vessels. $\cdot$ In human anatomy, the difference between terms is present (that is, between nerves or blood vessels which control the meridian muscle and those which pass near by). $\cdot$ The inner composition of the heart meridian muscle in the human arm is as follows: 1) Muscle H-l: latissimus dorsi muscle tendon, teres major muscle, coracobrachialis muscle H-2: biceps brachialis muscle, triceps brachialis muscle, brachialis muscle H-3: pronator teres muscle and brachialis muscle H-4: palmar carpal ligament and flexor ulnaris tendon H-5: palmar carpal ligament & flexor retinaculum, tissue between flexor carpi ulnaris tendon and flexor digitorum superficialis tendon, flexor digitorum profundus tendon H-6: palmar carpal ligament & flexor retinaculum, flexor carpi ulnaris tendon H-7: palmar carpal ligament & flexor retinaculum, tissue between flexor carpi ulnaris tendon and flexor digitorum superficial is tendon, flexor digitorum profundus tendon H-8: palmar aponeurosis, 4th lumbrical muscle, dorsal & palmar interrosseous muscle H-9: dorsal fascia, radiad of extensor digiti minimi tendon & extensor digitorum tendon 2) Blood vessel H-1: axillary artery, posterior circumflex humeral artery H-2: basilic vein, brachial artery H-3: basilic vein, inferior ulnar collateral artery, brachial artery H-4: ulnar artery H-5: ulnar artery H-6: ulnar artery H-7: ulnar artery H-8: palmar digital artery H-9: dorsal digital vein, the dorsal branch of palmar digital artery 3) Nerve H-1: medial antebrachial cutaneous nerve, median n., ulnar n., radial n., musculocutaneous n., axillary nerve H-2: median nerve, ulnar n., medial antebrachial cutaneous n., the branch of muscular cutaneous nerve H-3: median nerve, medial antebrachial cutaneous nerve H-4: medial antebrachial cutaneous nerve, ulnar nerve H-5: ulnar nerve H-6: ulnar nerve H-7: ulnar nerve H-8: superficial branch of ulnar nerve H-9: dorsal digital branch of ulnar nerve.

• 한방재활의학과학회지
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• 제24권4호
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• pp.83-96
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• 2014

Objectives Although many studies explored the topic of meridian sinew in various perspectives and the term "meridian sinew" is widely used, the theory of meridian sinew is not applied for precise diagnosis and in-depth treatment in clinical practice. The aim of the study is to provide basic data classifying muscles into meridian sinew for future studies that investigate meridian sinew based on an anatomical basis. Methods Studies were identified with searches of six major Korean databases: OASIS, KoreaMed, KMBASE, KISS, NDSL and KoreanTK. Published primary studies classifying muscles into meridian sinew were included. Results A total of 20 studies met the inclusion criteria and were included in the analysis. Twelve studies conducted the classification of muscles into meridian sinew based on meridian/ acupoints distribution and six based on meridian sinew distribution, and two based on both. Muscles with fidelity level of 50 or more were 54 (85.7%) and muscles with 100 fidelity level were 7 (11.3%): occipitalis, adductor digiti minimi, frontalis, biceps femoris, rectus femoris, vatus lateralis and extensor digitorum longus. Conclusions Classification results of muscles into meridian sinew varied according to the classification criteria and interpretation of meridian sinew and acupoints distribution. To develop muscle sinew as a more useful theory in diagnosis and treatment, efforts should be made to reduce the gap between study results and build consensus on the anatomical entity of meridian sinew.

• Journal of Yeungnam Medical Science
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• 제14권1호
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• pp.111-122
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• 1997

정상 성인에서 상지로 부터 H-반사가 유발될수 있는지를 알아보고, 또 상지에서의 H-반사 검사가 경수 신경근병증의 진단에 유용한지를 알고자 본 연구를 실시하였다. 정상 성인 31명을 대상으로 좌우 62개의 요측수근굴근, 요측수근신근, 상완요골근, 소지외전근의 H-반사를 검사하여 잠복기와 interlatency time을 구하였고 경수 신경근병변을 가진 환자 12명을 대상으로 H-반사를 검사하였다. 정상군에서 요측수근신근의 H-반사의 잠복기의 평균은 $15.99{\pm}1.25$ msec, 양측 차이의 평균치는 $0.68{\pm}0.71$ msec이었으며 interlatency time은 평균치가 $13.93{\pm}1.32$ msec, 양측 차이의 평균치는 $0.73{\pm}0.62$ msec 이었다 요측수근굴근의 H-반사의 잠복기의 평균은 $16.16{\pm}1.65$ msec, 양측 차이의 평균치는 $0.47{\pm}0.48$ msec이었고 interlatency time의 평균치는 $13.91{\pm}0.99$ msec, 양측 차이의 평균치는 $0.49{\pm}0.47$ msec 이었다. 상완요골근의 경우는 H-반사의 잠복기의 평균치가 $16.47{\pm}1.59$ msec, 양측 차이의 평균치가 $0.63{\pm}0.43$ msec 이었고 interlatency time의 평균치는 $14.68{\pm}1.61$ msec, 양측 차이의 평균치는 $0.79{\pm}0.71$ msec 이었다. 소지외전근에서의 H-반사의 잠복기의 평균치는 $24.46{\pm}1.42$ msec, 양측 차이의 평균치는 $0.59{\pm}0.42$ msec, 양측 차이의 평균치는 $0.59{\pm}0.42$ msec이고 interlatency time의 평균치는 $22.31{\pm}1.24$ msec, 양측 차이의 평균치는 $0.19{\pm}0.44$ msec를 보였다. 정상군에서는 팔 길이와 키가 커짐에 따라서 H-반사의 잠복기가 길어지는 양상을 보였다. 경수 신경근병변을 가진 12명중 11명에서 H-반사 검사상 이상 소견을 보였으며 제 6,7 경수 신경근 병변을 보인 5명중 4명에서 요측수근굴근의 H-반사의 이상 소견을 보였고, 제 7 경수 신경근병변을 보인 4명 모두에서 요측수근굴근과 요측수근신근에서의 이상 소견을 보였다. 제 5 신경근병변을 보인 환자 1명에서 상완요골근에서의 이상 소견을 보였다. 본 연구를 통하여 정상 성인에서 상지로부터 H-반사가 측정할 수 있으며, H-반사의 잠복기는 팔 길이와 키에 연관이 있음을 알았다. 또 경수 신경병증의 진단에 H 반사가 적용될 수 있음을 확인 하였다.