lectrophysiological examination was used in 15 cases of cubital tunnel syndrome before andduring opcration. The velocity, latency and amplitude of the conduction of the ulnar nerve 5cm aboveand below the elbew joint were measured by surface electrodes and direct stimulation. There is nosignificant difference(Pgt; 0.5 )between the results from the two kinds of testing. After the ulnarnerve was decompressed from the cubital tunnel, the conduction velocity increased by 50%, latency shortenee by 40%, the improvement in conduciton velocity being particularly significant(P lt; 0.02). which show that conduction velocity is a relatively sensitive testing parameter. Electrophysiological examination plays a monitoring role during cubital tunnel syndrome decompression.
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 relationship between the elbow flexion angle and the cubital tunnel pressure in patients with cubital tunnel syndrome. Methods Between June 2010 and June 2011, 63 patients with cubital tunnel syndrome were treated. There were 47 males and 16 females with an average age of 59 years (range, 31-80 years). The lesion was at left side in 18 cases and at right side in 45 cases. During anterior transposition of ulnar nerve, the cubital tunnel pressure values were measured at full elbow extension, elbow flexion of 30, 60, and 90°, and full elbow flexion with microsensor. The elbow flexion angle-cubital tunnel pressure curve was drawn. Results The cubital tunnel pressure increased smoothly with increased elbow flexion angle when the elbow flexed less than 60°, and the pressure increased sharply when the elbow flexed more than 90°. The cubital tunnel pressure values were (0.13 ± 0.15), (1.75 ± 0.30), (2.62 ± 0.34), (5.78 ± 0.47), and (11.40 ± 0.62) kPa, respectively at full elbow extension, elbow flexion of 30, 60, and 90°, and full elbow flexion, showing significant differences among different angles (P lt; 0.05). Conclusion The cubital tunnel pressure will increase sharply when the elbow flexes more than 90°, which leads to the chronic ischemic damage to ulnar nerve. Long-term ischemic damage will induce cubital tunnel syndrome.
Objective To provide anatomy evidence of the simple injury of the deep branch of the unlar nerve for cl inical diagnosis and treatments. Methods Fifteen fresh samples of voluntary intact amputated forearms with no deformity were observed anatomically, which were mutilated from the distal end of forearm. The midpoint of the forth palm fingerweb wasdefined as dot A , the midpoint of the hook of the hamate bone as dot B, the ulnar margin of the flexor digitorum superficial is of the l ittle finger as OD, and the superficial branch of the unlar nerve and the forth common finger digital nerve as OE, dot O was the vertex of the triangle, dot C was intersection point of a vertical l ine passing dot B toward OE; dot F was the intersection point of CB’s extension l ine and OD. OCF formed a triangle. OCF and the deep branch of the unlar nerve were observed. From May 2000 to June 2007, 3 cases were treated which were all simple injury of the deep branch of the unlar nerve by glass, diagnosed through anatomical observations. The wounds were all located in the hypothenar muscles, and passed through the distal end of the hamate bone. Muscle power controlled by the unlar nerve got lower. The double ends was sewed up in 2 cases directly intra operation, and the superficial branch of radial nerve grafted freely in the other 1 case. Results The distance between dot B and dot O was (19.20 ± 1.30) mm. The length of BC was (7.80 ± 1.35) mm. The morpha of OCF was various, and the route of profundus nervi ulnaris was various in OCF. OCF contains opponens canales mainly. The muscle branch of the hypothenar muscles all send out in front of the opponens canales. The wounds of these 3 cases were all located at the distal end of the hook of the hamate bone, intrinsic muscles controlled by the unlar nerve except hypothenar muscles were restricted without sensory disorder or any other injuries. Three cases were followed up for 2 months to 4 years. Postoperation, the symptoms disappeared, holding power got well, patients’ fingers were nimble. According to the trial standard of the function of the upper l imb peripheral nerve establ ished by Chinese Medieal Surgery of the Hand Association, the synthetical evaluations were excellent.Conclusion Simple injuries of the deep branch of the unlar nerve are all located in OCF; it is not easy to be diagnosed at the early time because of the l ittle wounds, the function of the hypothenar muscles in existence and the normal sense .
ObjectiveTo investigate the feasibility and effectiveness of unexposed ulnar nerve medial elbow incision, open reduction and internal fixation of anatomical locking compression plate (LCP) for distal humerus fractures.MethodsFourteen patients with distal humerus fracture were treated between January 2014 and June 2017. There were 5 males and 9 females, aged 18-85 years (mean, 65.5 years). The causes of injury included falling from height in 12 cases and traffic accident in 2 cases, all were closed fractures. Fractures were classified according to the AO/Association for the Study of Internal Fixation (AO/ASIF): 3 cases of type A2, 2 cases of type A3, 4 cases of type B2, 2 cases of type C1, 2 cases of type C2, and 1 case of type C3; without ulnar nerve damage. The time from injury to operation was 4-15 days, with an average of 7 days. The type B2 fractures were treated with unexposed ulnar nerve elbow medial incision and anatomic LCP internal fixation, the rest patients were all treated with unexposed ulnar nerve medial plus conventional lateral approach and bilateral LCP internal fixation.ResultsThe operation time was 50-140 minutes (mean, 80 minutes), and the intraoperative blood loss was 20-200 mL (mean, 70 mL). There was no blood vessels or nerve damage during operation. All incisions healed by first intension, and no incision infection occurred. All the 14 cases were followed up 9-24 months (mean, 13 months). X-ray films showed that all fractures healed within 4 months without complications such as nonunion and osteomyelitis. No ulnar nerve injury, cubitus varus deformity, and ossifying myositis occurred during follow-up. At last follow-up, the elbow function was assessed by Mayo Elbow Performance score (MEPS), the results were excellent in 8 cases, good in 4 cases, fair in 1 case, and poor in 1 case (type C3 fracture), with the excellent and good rate of 85.7%.ConclusionThe unexposed ulnar nerve medial elbow incision can be used effectively to reduct the fracture, and it is not prone to ulnar nerve injury. Combined with the lateral approach to treat the distal humerus fracture, which has the advantages of short operation time, few trauma, little bleeding, and reliable effectiveness.
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.
ObjectiveTo review the current progress of treatment of cubital tunnel syndrome (CTS). MethodsRecent relevant literature on the treatment of CTS was extensively reviewed and summarized. ResultsCTS is one of the most common peripheral nerve compression diseases.The clinical presentations of CTS consist of numbness and tingling in the ring and small fingers of the hand,pain in the elbow and sensory change following long-time elbow bending.Severe symptoms such as weakness or atrophy of intrinsic muscles of the hand and claw hand deformity may occur.The etiology of CTS is ulnar nerve compression caused by morphological abnormalities and nerve paralysis after elbow trauma.CTS can be treated by nonsurgical methods and surgery.Surgical options include in situ decompression,ulnar nerve transposition,medial epicondylectomy,and endoscopic release. ConclusionThere are multiple options to treat CTS,but the indication and effectiveness of each treatment are still controversial.Further studies are required to form a generally accepted treatment system.