ObjectiveTo determine the entry point and screw implant technique in posterior pedicle screw fixation by anatomical measurement of adult dry samples of the axis so as to provide a accurate anatomic foundation for clinical application. MethodsA total of 60 dry adult axis specimens were selected for pedicle screws fixation. The entry point was 1-2 mm lateral to the crossing point of two lines: a vertical line through the midpoint of distance from the junction of pedicle medial and lateral border to lateral mass, and a horizontal line through the junction between the lateral border of inferior articular process and the posterior branch of transverse process. The pedicle screw was inserted at the entry point. The measurement of the anatomic parameters included the height and width of pedicle, the maximum length of the screw path, the minimum distance from screw path to spinal canal and transverse foramen, and the angle of pedicle screw. The data above were provided to determine the surgical feasibility and screw safety. ResultsThe width of upper, middle, and lower parts of the pedicle was (7.35±0.89), (5.50±1.48), and (3.97±1.01) mm respectively. The pedicle height was (9.94±1.16) mm and maximum length of the screw path was (25.91±1.15) mm. The angle between pedicle screw and coronal plane was (26.95±1.88)° and the angle between pedicle screw and transverse plane was (22.81±1.61)°. The minimum distance from screw path to spinal canal and transverse foramen was (2.72±0.83) mm and (1.98±0.26) mm respectively. ConclusionAccording to the anatomic research, a safe entry point for C2 pedicle screw fixation is determined according to the midpoint of distance from the junction of pedicle medial and lateral border to lateral mass, as well as the junction between the lateral border of inferior articular process and the posterior branch of transverse process, which is confirmed to be effectively and safely performed using the entry point and screw angle of the present study.
【Abstract】Objective To study the anatomy of the hepatic arteries and imitate the way to deal with the hepatic arteries in the living liver transplantation of the left lateral lobe.Methods Thirty normal adult livers were anatomyzed and 30 casting models of livers were observed. The lengths, diameters and distributaries of the hepatic arteries were described.Results The blood supply of the left lateral region came from proper hepatic artery, left hepatic artery and middle hepatic artery. The aberrant arteries included left inferior phrenic artery, left gastric artery and right gastric artery. They branched to supply the upper segment and the inferior segment.Conclusion There are five types of hepatic arteries to supply the left liver lobe. The anatomy of hepatic arteries should be studied and a reasonable approach to gain a liver graft should be designed before transplantation. The hepatic arteries should be dealt with so as to anastomose with recipient hepatic arteries.
Objective To observe and measure the approach next to the erector spinae in the thoracic and lumbar segments of the spine and adjacent anatomical structures by the topographic method, to clarify the positioning method and safe range so as to provide the anatomical basis of the approach for spinal canal decompression. Methods Twelve formaldehyde-treated adult cadaver specimens were selected, including 6 males and 6 females with an average age of 43 years (range, 27-52 years) and with an average height of 166 cm (range, 154-177 cm). The related data of the approach at T1-S1 levels were respectively measured: the distance between the lateral edge of the erector spinae and the spinous process, the length of the approach, the angle between the approach and the horizontal plane, the size of intervertebral foramen, and the vertical distance between the segmental artery and the upper edge of the vertebrae. Results The distance between the lateral edge of the erector spinae and the spinous process ranged from (41.75 ± 3.29) mm to (74.54 ± 7.08) mm. The length of the approach ranged from (66.75 ± 10.81) mm to (97.13 ± 13.35) mm. The angle between the approach and the horizontal plane ranged from (38.38 ± 6.16)° to (53.67 ± 4.40)°. The vertical distance between the segmental artery and the upper edge of the vertebrae ranged from (9.50 ± 0.60) mm to (18.30 ± 1.56) mm. The size of foraminal was also measured. The spinal canal could reach when iliocostalis lateral edge was used as the starting point in the lumbar segments, and longissimus lateral edge as the starting point in the thoracic segments. It was confirmed that there was enough safe space for the spinal decompression without the resection of the articular process. Conclusion The approach next to the erector spinae can reach spinal canal to achieve the purpose of decompression through the intervertebral foramen. The minimally invasive approach is feasible and safe. It has the value of the operative application.
【Abstract】 Objective To investigate the feasibil ity of contralateral C7 nerve transfer via posterior spinal route fortreatment of brachial plexus root avulsion injury by anatomical study. Methods Ten cadaveric specimens of 7 men and3 women were selected, who had no obvious deformity and no tissue defect in neck neutral position. By simulating surgical exploration of brachial plexus injury, the length of contralateral C7 nerve root was elongated by dissecting its anterior and posterior divisions to the distal end, while the length of C7 nerve from the intervertebral foramen to the branching point and the length of the anterior and posterior divisions were measured. By simulating cervical posterior approach, the C7 vertebral plate and T1 spinous process were fully exposed; the hole was made near vertebral body; and the C7 nerve root lengths by posterior vertebra path to the contralateral upper trunk and lower trunk were measured. Results C7 nerve root length was (58.62 ± 8.70) mm; the length of C7 nerve root plus posterior or anterior division was (65.15 ± 9.11) mm and (70.03 ± 10.79) mm, respectively. By posterior spinal route, the distance was (72.12 ± 10.22) mm from the end of C7 nerve to the contralateral upper trunk of brachial plexus, and was (95.21 ± 12.50) mm to the contralateral lower trunk of brachial plexus. Conclusion Contralateral C7 nerve can be transferred to the contralateral side through posterior spinal route and it only needs short bridge nerve or no. The posterior spinal route can effectively prevent from neurovascular injury, so it might be the best surgery approach for the treatment of brachial plexus root avulsion injury.
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.
Objective To study the hook of hamate bone by anatomy and iconography methods in order to provide information for the cl inical treatment of injuries to the hook of hamate bone and the deep branch of ulnar nerve. Methods Fifty-two upper l imb specimens of adult corpses contributed voluntarily were collected, including 40 antisepticized old specimens and 12 fresh ones. The hook of hamate bone and its adjacent structure were observed. Twentyfour upper l imbs selected randomly from specimens of corpses and 24 upper l imbs from 12 healthy adults were investigated by computed tomography (CT) three-dimensional reconstruction, and then related data were measured. The measurement results of24 specimens were analyzed statistically. Results The hook of hamate bone is an important component of ulnar carpal canal and carpal canal, and the deep branch of ulnar nerve is located closely in the inner front of the hook of hamate bone. The flexor tendons of the forth and the l ittle fingers are in the innermost side, closely l ie next to the outside of the hook of hamate bone. The hamate bone located between the capitate bone and the three-cornered bone with wedge-shaped. The medial-, lateral-, and front-sides are all facies articularis. The hook of hamate bone has an approximate shape of a flat plate. The position migrated from the body of the hamate bone, the middle of the hook and the enlargement of the top of the hook were given the names of “the basis of the hook”, “the waist of the hook”, and “the coronal of the hook”, respectively. The short path of the basement are all longer than the short path of the waist. The long path of the top of the hook is the maximum length diameter of the hook of hamate bone, and is longer than the long path of the basement and the long path of the waist. The iconography shape and trait of the hook of hamate bone is similar to the anatomy result. There were no statistically significant differences (P gt; 0.05) between two methods in the seven parameters as follows: the long path of the basement of the hook, the short path of the basement of the hook, the long path of the waist of thehook, the short path of the waist of the hook, the long path of the top of the hook, the height of the hook, of hamate bone, and the distance between the top and the waist of the hook. Conclusion The hook of hamate bone can be divided into three parts: the coronal part, the waist part, and the basal part; fracture of the hamate bone can be divided into fracture of the body, fracture of the hook, and fracture of the body and the hook. Facture of the hook of hamate bone or fracture unnion can easily result in injure of the deep branch of ulnar nerve and the flexor tendons of the forth and the l ittle fingers. The measurement results of CT threedimensional reconstruction can be used as reference value directly in cl inical treatments.
Objective To investigate the anatomical evidence of low end-to-side anastomosis of median nerve and ulnar nerve in repair of Dejerine Klumpke type paralysis or high ulnar nerve injury. Methods Twelve formaldehyde anticorrosion specimens (24 sides) and 3 fresh specimens (6 sides) were observed. There were 9 males (18 sides) and 6 females(12 sides). The specimen dissected under the microscope. S-shape incision was made at palmar thenar approaching ulnar side, the profundus nervi ulnaris and superficial branch of ulnar nerve were separated through near end of incision, and the recurrent branch of median nerve and comman digital nerve of the ring finger were separated through far end of incision. The distances from pisiform bone to the start point of the recurrent branch of median nerve, and to the start point of comman digital nerve of the ring finger were measured. The width and thickness of the profundus nervi ulnaris and superficial branch of ulnar nerve, and the recurrent branch of median nerve and comman digital nerve of the ring finger were measured, and the cross-sectional area was calculated. The number of nerve fiber was determined with HE staining and argentaffin staining. Results The crosssectional area and the number of nerve fiber were (2.46 ± 1.03) mm2 and 1 305 ± 239 for the profundus nervi ulnaris, (2.62 ± 1.75) mm2 and 1 634 ± 343 for the recurrent branch of median nerve, (1.60 ± 1.39) mm2 and 1 201 ± 235 for the superficial branch of ulnar nerve, and (2.19 ± 0.89) mm2 and 1 362 ± 162 for the comman digital nerve of the ring finger. There were no significant differences (P gt; 0.05) in the cross-sectional area and the number of nerve fiber between the profundus nervi ulnaris and the recurrent branch of median nerve, between the superficial branch of ulnar nerve and the comman digital nerve of the ring finger; and two factors had a l inear correlation (P lt; 0.05) with correlation coefficients of 0.68, 0.66 and 0.56, 0.36. The distances were (36.98 ± 4.93) mm from pisiform bone to the start point of the recurrent branch of median nerve, and (28.35 ± 6.63) mm to the start point of comman digital nerve of the ring finger. Conclusion Low end-to-side anastomosis of median nerve and ulnar nerve has perfect match in the cross-sectional area and the number of nerve fiber.
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 the appl ication of the superficial inferior epigastric artery flap. Methods Ten cadavers which were immersed in formal in less than 6 months and were perfused by red latex were used in this study. There were 8 males and 2 females with an average age of 58 years (range, 35-78 years). The origin, course, branch,distribution, diameter, pedicle length, and neighbour of superficial inferior epigastric artery and vein were observed in the 2 sides of inguinal region. Results In these series of 10 cadaver (20 sides) dissections, the superficial inferior epigastric artery was identified in 18 sides, which average cal iber was 1.48 mm with a mean vascular pedicle length of 4.80 cm. In 11 sides, the superficial inferior epigastric artery arose aspart of a common trunk with one or more other vessels; in other 7, it originated from the femoral. There were 4 branch modes of superficial inperior epigastric artery: single trunks (5 sides), double ramification (3 sides), single lateral ramification (7 sides), and single medial ramification (3 sides). The superficial inferior epigastric vein was observed in 20 sides, which average cal iber was 2.33 mm with a mean sides pedicle length of 5.45 cm. In 8 sides, the venous drainage was as an individual vein; in 12 sides, both patterns were observed (a pair of venae comitantes and an individual vein). Conclusion The inferior epigastric artery flap can be appl ied to microsurgical flap transfer, potentially in breast reconstruction, phalloplasty, reconstruction of head, neck and four l imbs defects.
Objective To obtain the anatomical data of the insertions of the lateral collateral l igament (LCL), popl iteus tendon (PT), and popl iteofibular l igament (PFL) for the posterolateral corner of the knee (PLC) reconstruction. Methods Thirty human cadaveric knees were chosen to observe the structure of PLC, including 14 males and 16 females with an averageage of 55 years (range, 45-71 years ). The insertions of LCL, PT, and PFL were identified, then the distances from the centers of the insertions to specific bony landmarks were measured, which were lateral epicondyle, the most proximal point on the styloid process and the most anterior point on the anterior surface of the fibular head. Normal ization processing of the actual numerical values from each knee was performed. Results The center of the LCL insertion was at the site of (1.27 ± 3.10) mm proximal and (2.99 ± 1.29) mm posterior to the lateral epicondyle of the femur respectively, and the center of the PT insertion was at the site of (8.85 ± 3.38) mm distal and (3.83 ± 1.95) mm posterior to the lateral epicondyle of the femur respectively. The center of the LCL insertion was at the site of (10.56 ± 2.17) mm distal and (7.51 ± 1.81) mm anterior to the nearest point of the fibular styloid respectively, and the center of the PFL insertion was at the sites of (1.31 ± 0.55) mm distal and (0.49 ± 1.36) mm anterior to the nearest point of the fibular styloid respectively. The cross-sectional area of the insertions of femur was (44.96 ± 13.29) mm2 for the LCL and (52.52 ± 11.93) mm2 for the PT, respectively; the cross-sectional area of the insertions of fibula was (35.93 ± 11.21) mm2 for the LCL and (14.71 ± 6.91) mm2 for the PFL, respectively. Conclusion The LCL, PT, and PFL have a consistent pattern of insertion.