Objective To provide the anatomic bases for clinical application of the second dorsal metacarpal artery(SDMA) island flap with double pivot points. Methods The origin,branches and distribution of the recurrent cutaneous branch of the SDMA were observed in 30 adult fresh cadaver specimens, which were illustrated with special dye.Eighteen cases of skin defets of the thumb were repaired with the SDMA island flap. The defect locations were the dorsal part in 11 cases and palmar part in 7 cases, including 3 cases of defect in association with long pollical extensor defect and 2 cases of defect in association with dorsal skin defect of proximal finger. The flap area ranged from 2 cm×3 cmto 3 cm×5 cm. Results The appearance of therecurrent cutaneous branch of the SDMA was observed in all cases(100%), which originated 0.5±0.2 cm distant from the distal intersectiones between the SDMA and the index extensor and disappeared 1.2±0.5 cm distant from the proximal metacarpophalangeal joint. The branches of 1.7±0.7 were seen with a longitudinal fan-like distributionforward proximal part on the deep surface of the dorsal superficial vein. The exradius and the length of the recurrent cutaneous branch of the SDMA were 0.3±0.1 mm and 6.5±0.8 mm, respectively. The transplanted flaps survived in all cases and 16 cases were followed up for 8-14 months. The colour and appearance of the skin were satisfactory. The two-point discriminations were 0.9 mm in 3 cases by bridging digital nerve and 1.1 mm in 9 cases by anastomosing dorsal digital nerve; while the two-point discrimination was 13-15 mm in 4 cases without anastomosing nerve. Conclusion The origin,branches and distribution of the recurrent cutaneous branch of the SDMA is constant, which provide a potentially longer pedicle and increase the possibility to rotate the flap and also avoid the donor skin defect of rotation of the flap.
Objective To explore the arterial origin and the distribution of the extracranial branches of the facial nerve. Methods Red latex or red chlorinated polyvinyl chloride was injected into the arteries of 15 fresh adult head specimens by both common carotid artery catheterization. The arterial origin and distribution of the extracranial branches of the facial nerve were observed. Results The nutrient arteries of the extracranial branches of the facial nerve originated from stylomastoid artery of the posterior auricular artery, the facial nervous branch of superficial temporal artery, transverse facial artery, superior and inferior facial nervous branches of external carotid artery and the posteriorand anterior facial nervous branches of external carotid artery. The outer diameters of them were (0.8±0.2) mm, (0.9±0.4) mm, (1.9±0.3) mm, (1.0±0.2) mm, (1.1±0.4) mm, (1.0±0.2) mm and (1.1±0.6) mm respectively. The sub-branches ofthe attendant artery of the facial nerve anastomosed each other in addition to supplying their own nerve, and a rich vascular network was formed between the facial nerve and adjacent tissue. Conclusion The study on blood supply of the extracranial segment of the facial nerve can provide anatomic basis for avoiding injury of the nutrient arteries of the facial nerve during operation of the parotidean and masseteric region clinically.
Objective To provide the anatomic basis for thelag screw placement in the anterior column of the acetabulum. Methods Twenty-two pelvis specimens with 44 acetabula of the native adult cadavers were studied. The anthropometric measurement was performed on 44 acetabula to determine the shape of the transverse section of the anterior column of the acetabulum, the optimal entry point for the lag screw on the outer table of the ilium, the direction of the screw, and the distance from the entry point to the obturator groove. Results The transverse section of the anterior column of the acetabulum was almost triangle-shaped. The path for the lag screw placement was 10.5±0.8 mm in diameter. The optimal entry point on the posterolateral ilium for the screw fixation was found toexist 9.2±2.4 mm superior to the line between the anterior superior iliac spine and the greater sciatic notch and 38.5±3.8 mm superior to the greater sciatic notch. The distance from the entry point to the obturator groove was 84.1±6.2 mm. The inclination of the lag screw was 54.2±5.5° at the caudal direction in the sagittal plane and 40.7±3.8° in the horizontal plane. The device for the safe screw placement in the anterior column was designed. Conclusion The above datacan facilitate an insertion of one 6.5 mm lag screw into the anterior acetabular column and minimize the risk of articular violation or cortical penetration, which has a narrow margin of safety. The safe length of the lag screw should be 70 mm.The optimal entry point on the posterolateral ilium for the screw fixationis determined to be 10 mm superior to the line between the anterior superior iliac spine and the greater sciatic notch and 40 mm superior to the greater sciatic notch. The inclination of the lag screw should be 55° at the caudal direction in the sagittal plane and 40° in the horizontal plane. It is safe to place thelag screw in the anterior column with the help of the targeting device.
Objective To study the vascular applied anatomy,the anatomic features of fascial,and interfascial space around the pancreas and duodenum,observe marker and safe surgical plane of pancreaticoduodenal region,and provide clinical anatomy basis for surgery of duodenum, pancreatic head,and distal common bile duct.Methods Anatomical observations were performed in 7 formalin fixed cadavers on duodenum,distal common bile duct,and pancreatic peripheral blood supply.Transverse mesocolon,pancreatic capsule and potential interfascial space,surgical plane and anatomic marker for reorganization around pancreas were observed.Results Gastropancreatic fold and hepatopancreatic fold formed by pancreatic capsule were good markers to locate the root of left gastric artery and common hepatic artery.A vessel-free plane between the behind pancreas and the anterior lamella of Gerota fascia could be used to make lymphadenectomy and pancreatic dissection behind pancreas and duodenum.Gerota fascia should be regarded as a safe posterior border to avoid injuring vessels and adrenal gland by mistake.The descending part and horizontal part of duodenum were mainly supplied by the anterior and posterior pancreaticoduodenal arterial arcade.The anterior and posterior pancreaticoduodenal arterial arcade should be protected in duodenum-preserving resection of pancreatic head.Conclusions Full understanding of pancreatic fascial and interfascial space formed in embryonic development is very important.Operation along the interfascial spaces is safe without bleeding and organ injury,which is essential in oncosurgery.
目的:通过对滑车神经行经小脑幕侧方区域的应用解剖学研究,寻找小脑幕侧方区域手术时避免损伤滑车神经的临床解剖标志。方法:对15例(男10例,女5例)防腐固定无畸形、无病变的成人头颅标本用红色乳胶灌注后,10倍手术显微镜下观察滑车神经在小脑幕侧方区域的行径,及其与周围重要神经、血管结构的毗邻关系,测量滑车神经长度、宽度、厚度及其与周围标志点的距离,并对所得结果进行统计学分析。结果:滑车神经在小脑上动脉和大脑后动脉之间向前行,进入小脑幕侧方区域,在动眼神经三角的后部穿越游离缘硬膜,其长度为(6.78±1.87)mm,宽度为(1.09±0.21)mm,厚度为(0.78±0.11)mm。滑车神经进入小脑幕侧方区域的入口处位于前床突、颈内动脉床突上段起始部、动眼神经入口后方,位于后床突后外方;距离前床突(23.24±3.18)mm、颈内动脉床突上段起始部(17.57±3.26)mm、动眼神经入口(11.42±3.32)mm;距离后床突(14.21±3.25)mm。结论:行小脑幕侧方区域手术时,为避免损伤滑车神经,前床突、后床突、颈内动脉床突上段起始部和动眼神经入口可以作为寻找滑车神经入口的重要标志,同时注意区分小脑上动脉和大脑后动脉。
Objective To investigate the blood supply of the ulnar nerve in the elbow region and to design the procedure of anterior transposition of ulnar nerve accompanied with arteries for cubital tunnel syndrome.Methods The vascularity of the ulnar nerve was observed and measured in20adult cadaver upper limb specimens. And the clinical surgical procedure was imitated in 3 adult cadaver upper limb specimens. Results There were three major arteries to supply the ulnar nerve at the elbow region: the superior ulnar collateral artery, the inferior ulnar collateral artery and the posterior ulnar recurrent artery. The distances from arterial origin to the medial epicondyle were 14.2±0.9, 4.2±0.6 and 4.8±1.1 cm respectively. And the total length of the vessels travelling alone with the ulnar nerve were 15.0±1.3,5.1±0.3 and 5.6±0.9 cm. The external diameter of the arteries at the beginning spot were 1.5±0.5, 1.2±0.3 and 1.4±0.5 mm respectively. The perpendicular distance of the three arteries were 1.2±0.5,2.7±0.9 and 1.3±0.5 cm respectively.Conclusion It is feasible to perform anterior transposition of the ulnar nerve accompanied with arteries for cubital tunnel syndrome. And the procedure preserves the blood supply of the ulnar nerve following transposition.
Objective To investigate the anatomic foundation of using main branch of posterior femoral nerve to restore the sensation function of distal basedsural island flap. Methods Thirty cases of adult human cadaver legs fixed by 4%formaldehyde were used. Anatomical investigation of the posterior femoral nerves of lower legs was conducted under surgical microscope to observe their distribution, branches and their relationship with small saphenous vein. Nerve brancheswith diameter more than 0.1 mm were dissected and accounted during observation.The length and diameter of the nerves were measured. Results The main branch of posterior femoral nerve ran downwards from popliteal fossa within superficial fascia along with small saphenous vein. 70% of the main branch of the posterior femoral nerves lay medially to small saphenous vein, and 30% laterally. They wereclassified into 3 types according to their distribution in lower legs: typeⅠ (33.3%) innervated the upper 1/4 region of lower leg (region Ⅰ), type Ⅱ (43.3%) had branches in upper 1/2 region (region Ⅰ and Ⅱ), and type Ⅲ (23.3%) distributed over the upper 3/4 region (region Ⅰ, Ⅱ and Ⅲ). In type Ⅱ, the diameter of the main branches of posterior femoral nerves in the middle of popliteal tossa was 10±04 mm and innervated the posterior upper-middle region (which was the ordirary donor region of distal based sural island flaps) of lower legs with 2.0±0.8 branches, whose diameter was 0.3±0.2 mm and length was 3.5±2.7 mm. The distance between the end of these branches and small saphenous vein was 0.8±0.6 mm. In type Ⅲ, their diameter was 1.2±0.3 mm and innervated the posterior upper-middle region of lower legs with 3.7±1.7 branches, whose diameter was 0.4±0.1 mm and length was 3.7±2.6 mm. The distancebetween the end of these branches and small saphenous vein was 0.8±0.4 mm. Conclusion 66.6% of human main branch of posteriorfemoral nerves (type Ⅱ and type Ⅲ) can be used to restore the sensation of distal based sural island flap through anastomosis with sensor nerve stump of footduring operation.
Objective To provide the anatomic evidences and the choice of tendon graft for anatomic reconstruction of posterolateral complex through the morphological and biomechanical study on posterolateral structures of the knee in normal adult cadavers. Methods Twenty-three fresh lower l imb specimens from voluntary donators and 9 lower l imbs soaked by Formal in were selected for anatomic study on the posterolateral complex of the knee. Six fresh specimens were appl ied to measure the maximum load, intensity of popl iteus tendon, lateral collateral l igament, and popl iteofibular l igament, which were key components of the posterolateral complex. Results Popl iteus musculotendinous junction was located at 7.02-11.52 mm beneath lateral tibial plateau and 8.22-13.94 mm medially to fibular styloid process. The distances from femoral insertion of popl iteus tendon to the lower border of femoral condyle and to posterior edge of femoral condyle were 10.52-14.38 mm and 14.24-26.18 mm, respectively. Popl iteofibular l igament originated from popl iteus musculotendinous junction and ended at fibular styloid process. Lateral collateral l igament was located at 10.54-16.48 mm inferior to fibular styloid process, and the distances from femoral insertion to the lower border of femoral condyle and to posterior edge of femoral condyle were 14.92-19.62 mm and 14.66-27.08 mm, respectively. The maximum load and intensity were 579.60-888.40 N and 20.50-43.70 MPa for popl iteus tendon, were 673.80-1 003.20 N and 24.30-56.40 MPa for lateral collateral l igament, and were 101.56-567.35 N and 8.94-36.16 MPa for popl iteofibular l igament, respectively. Conclusion During anatomical reconstruction of posterolateral complex, the bony tunnel of the key components should be located according to the insertion mentioned above. On the basis of this study, the maximum load and intensity of selectable grafts should exceed 833 N and 36 MPa.
Objective To provide the anatomical basis for posterior femoral neurocutaneous vascular flap pedicled with direct popliteal artery perforator. Methods A total of 30 embalmed lower limbs of adult cadavers perfused with red latex were dissected and measured to observe the course and distribution of posterior femoral cutaneous nerve (PFCN), and the anastomoses between direct popliteal artery perforator and nutrient vessels of PFCN. Mimic operation was performed on 1 side of fresh specimen. Results PFCN started from the midpoint of the inferior gluteus maximus edge, and went down along the middle line of posterior thigh region, and the final trunk of PFCN accompanied with small saphenous vein down to the middle line of lower leg. The diameters of PFCN was (3.0 ± 0.6) mm at the inferior gluteus maximus edge, and was (2.0 ± 0.7) mm at the superior fossa poplitea. The nutrient vessels of PFCN were multi-segmental and polyphyletic. The direct popliteal artery perforator which started from popliteal artery directly was constant pierced into deep fascia about 7-11 cm above the knee joint, and its original diameter was (0.8 ± 0.2) mm. The direct popliteal artery perforator had 1-2 accompanying veins, and this perforator artery was the main nutrient vessel of the inferior segment of PFCN. The direct popliteal artery perforator gave off 5-8 small vessels which anastomosed with the 1st-3rd perforator of deep femoral artery, the obturator artery perforator, and the lateral femoral circumflex artery perforators. Then these nutrient vessels formed vascular plexus along PFCN in the middle line of posterior region of thigh. Mimic operation showed that the posterior femoral neurocutaneous vascular flap pedicled with direct poplitea artery perforator could be formed successfully. Conclusion The posterior femoral neurocutaneous vascular flap pedicled with direct popliteal artery perforator has constant blood supply and can be easily formed to repair defects around knee joint.
To provide anatomical evidences for the blood supply compound flap based on fibular head to rebuild internal malleolus. Methods The morphology of vessels and bones in donor site and in recipient site was observed. The materials for the study were l isted as follows: ① Forty desiccative adult tibias (20 left and 20 right respectively) were used to measure the basilar width, middle thickness, anterior length, posterior length and introversion angle of internal malleolus; ② Forty desiccative adult fibulas (20 left and 20 right respectively) were used to measure the middle width and thickness, as well as the extraversion angle of articular surface of fibular head; ③ Thirty adult lower l imb specimens which perfused with red rubber were used to observe the blood supply relationships between the anterior tibial recurrent vessels and fibular head, and internal anterior malleolar vessels inside recipient site. Results The internal malleolus had a basilar width of (2.6 ± 0.2) cm, a middle thickness of (1.3 ± 0.2) cm, an anterior length of (1.4 ± 1.9) cm and a posterior length of (0.6 ± 0.1) cm. Its articular facet was half-moon. Its introversion angle was (11.89 ± 3.60)°. The fibular head had a middle thickness of (1.8 ± 0.6) cm, a middle width of (2.7 ± 0.4) cm. Its articular facet was toroid, superficial and cavate in shape, and exposed inwardsly and upwardsly, and had a extraversion angel of (39.2 ± 1.3)°. The anterior tibial recurrent artery directly began from anterior tibial artery, accounting for 93.3%. Its initiation point was (4.5 ± 0.7) cm inferior to apex of fibular head. Its main trunk ran through the deep surface of anterior tibial muscle, and ran forwards, outwards and upwards with sticking to the lateral surface of proximal tibia. Its main trunk had a length of (0.5 ±0.2) cm and a outer diameter of (2.0 ± 0.4) mm. Its accompanying veins, which had outer diameters of (2.1 ± 0.5) mm and (2.6 ± 0.4) mm, entry into anterior tibial vein. It constantly gave 1-2 fibular head branches which had a outer diameter of (1.7 ± 1.3) mm at (1.0 ± 0.4) cm from the initiation point. The internal anterior malleolar artery which began from anterior tibial artery or dorsal pedal artery had a outer diameter of (1.6 ± 0.4) mm. Its accompanying veins had outer diameters of (1.3 ± 0.5) mm and (1.1 ± 0.4) mm. Conclusion The blood supply compound flap based on fibular head had a possibil ity to rebuild internal malleolus. Its articular facet was characterized as the important anatomical basis to rebuild internal malleolus.