Methods: The study group consists of 229 myasthenia gravis patients without thymoma, (164 females, 65 males; mean age 35.6 years; range 9 to 70 years). Postoperative complications and relations with age, gender, duration of symptoms, the clinical stage of the disease, the type of the operative procedure and medication were analyzed. The study population was divided into five groups according to their preoperative medication. Group 1 (n=51) Cholinesterase inhibitors, group 2 (n=30) Corticosteroids, group 3 (n=125) Cholinesterase inhibitors and Corticosteroids, group 4 (n=13) Immunosuppressants, Cholinesterase inhibitors and Corticosteroids, and group 5 (n=10) No medication. Postoperative complications were: i) Infectious complications (n=18), ii) Myasthenic complications (n=14), and iii) Others (n=7).
Results: There was not any statistically significant relation between complications and analyzed data other than subgroup of medications. Patients who had cholinesterase inhibitors, immunosuppressive therapy with additional corticosteroids had increased number of complications (p=0.004).
Conclusion: Concomitant administration of immunusupressants, cholinesterase inhibitors and corticosteroids to patients with Myasthenia Gravis could increase the number of complications following transsternal thymectomy.
There is a consensus that all adults with generalized MG should have a thymectomy because of the propagated evidence of the safety of the procedure and excellent outcome. The goal of thymectomy is to induce remission, or improvement, permitting a reduction in immunosuppressive medication.[1] This study specifically focused on postoperative complications and the patients medication on MG patients.
Patients were analyzed according to age, gender, duration of symptoms, clinical stage of the disease, perioperative medication and postoperative complications. Patients were divided into five groups according to their perioperative medication. Group 1 (n=51) Cholinesterase inhibitors, group 2 (n=30) Cortiosteroids, group 3 (n=125) Cholinesterase inhibitors and Cortiosteroids, group 4 (n=13) Immunosuppressants, Cholinesterase inhibitors and Cortiosteroids, and group 5 (n=10) No medication. Patients with no medication were the ones who were considered to be in remission period after a period of medical therapy. Duration of corticosteroid therapy was analyzed postoperative complications were; i) infectious complications (n=18): wound infection, sternal dehiscence, sternal osteomyelitis, sternal mobility, mediastinitis, pneumonia, ii) myasthenic complications (n=14): reintubation, prolonged intubation, iii) others (n=7): gastrointestinal bleeding, atelectasis, pleural effusion, arrythmia, reccurent larengeal nerve and transient - persistant phrenic nerve injury. Prolonged intubation was considered a mechanical ventilation period longer than 24 hours.
The thymectomy patients were usually scheduled as the first case of the day and medication was the usual first daily dose of the prescribed drugs. During complete thymectomy with partial sternotomy, all thymic tissue with particular care to neck, aortapulmonary window, and inferior to left innominate vein area was removed with available fat tissues in the mediastinum. Extended thymectomy was employed according to technique described by Mulder.[3] All patients were given prophylactic antibiotic in the beginning of operation and followed for 3 consecutive days. Neurologists had daily visits after the operation and regimen was managed. In some patients receiving corticosteroids, we employed Robicsek technique[4] in sternum closure when the sternum was considered to be osteoporotic.
Fishers exact test and Chi-square test were used for the statistical analyses.
Other factors. Complications were analysed according to age (over 35 years vs. younger) and gender. Both of them were statistically insignificant factors for the development of complications (Fishers exact test: p=0.67, p=0.79). Duration of symptoms, the clinical stage of the disease and the type of the operative procedure (complete thymectomy vs extended thymectomy) were noticed to be statistically insignificant factors (p=0.42 and p=0.48 and p=0.07). In corticosteroid administered patients, duration of corticosteroid therapy (0-6 months vs. 6-12 months vs. more than 12 months) was determined to be a statistically insignificant factor in the development of complications (p=0.36).
Medication and complications. The perioperative medication and complications can be seen in Table 1. The incidence of complications was similar between patients receiving corticosteroids with any combination of drugs and patients who were not receiving corticosteroids (p=0.69). Patients who were receiving cholinesterase inhibitors and additional immunosuppresant (azothioprine or cyclosporine) therapy with corticosteroids had increased number of complications (p=0.004) (Table 1).
Table 1: Perioperative medication and number of complications
Treatment of complications. Infectious complications were treated with conventional therapies. The major complication was mediastinitis. Three patients experienced this complication and one mortality occurred. In all of them our treatment consisted of revision with debritement with appropriate placement of irrigation and drainage catheters and culture specific antibiotics. Myasthenic medication was revised and in two successfully treated patients intravenous immunoglobulin therapy was employed. In sternal dehiscence major consideration was to revise the sternum closure with Robicsek technique with appropriate drainage catheters. Sternal mobility was not treated surgically, preferred approach was elastic sternal jackets. Plasmapheresis was the most commonly employed procedure in patients with prolonged intubation (7/11 patients, 63%).
Perioperative medication during the thymectomy procedure in MG is still debatable. Every tertiary clinic developed their own approach for surgical techniques and perioperative medication. No agreement exists on the optimal regimen in the perioperative period of thymectomy for MG. Although some authors prefer immunosuppressants, the majority are in favor of using cholinesterase inhibitors and plasmapheresis in the fear of serious postoperative complications. Seggia and colleagues[5] demonstrated that, perioperative plasmapheresis improved respiratory function and muscle strength and decreased hospital stay and cost. Our clinics attitude towards preoperative plasmapheresis is restricted only to severe MG patients who are unable to eat and drink and with restricted pulmonary functions. In the preoperative period only 3 patients (1.3%) neccessitated plasmapheresis, whereas 7 (3.0%) of 11 prolonged intubation patients had plasmapheresis in the postoperative period. Plasmapheresis may be used on an urgent basis in myasthenic crisis with respiratory embarrasment. Plasmapheresis and intravenous immunoglobulin therapy have been used widely in the treatment of MG to affect rapid short term improvement.[6] In some patients with higher stage Osserman- Genkins classification, severe exacerbations and impending crisis combining these two therapies may be advisable, however we are against routine use of these therapies in the preoperative period due to high cost, need for specialized staff and equipment. Our results with higher postoperative complication rates in patients with extended preoperative treatment (cholinesterase inhibitors, immunosuppressants and corticosteroids) suggest that plasmapheresis and intravenous immunoglobulin therapies could be considered for this group of patients in the preoperative period. The evident data would force us to perform the short term immunotherapies in the preoperative period. It is evident from the patients and methods of this article, that corticosteroid therapy was the main medication in the perioperative period. Types of infection (Pneumonia, mediastinitis, wound infection, etc.) which is supposed to be major complication, especially in patients with corticosteroid therapy could not be shown to be an important complication in our study group. In a similar study, postoperative wound infection and mediastinitis were found to be unrelated with the preoperative immunosuppression.[7] This result supports our data. In another series, the number of postoperative major complications were so high that it is deemed to be unacceptable (71/324).[8] In this study, postoperative management was administered according to a standardized protocol of anticholinesterase medication, which was withdrawn for the 48 hours of obligatory postoperative mechanical ventilation.[8] Thus; it is reasonable to continue with the same medication on which the patient has appeared to be in his best condition, even the regimen consists of corticosteroids. Our results demonstrated that our complication rate is 17.0% with such a wide spectrum of defined complications unforeseen in any prior study. Patients having corticosteroids did not have more complications than other patients. But on the other hand; immunosuppressants (azothioprine and cyclosporine) affected the number of postoperative complications adversely. The problem is thought to be due to the operations being transsternal. Probably this combination would cause no complication in minor thymectomy procedures such as video assisted and transcervical. Authors employing these procedures did not offer to taper the regimen in the perioperative period.[9,10] It was concluded that the long term clinical outcome after transcervical thymectomy is the same as after more radical operations, and also this technique was reported to carry a lower morbidity, a briefer hospitalisation period and a faster recovery.[11-13] In a study, performed by the author of this article, we found that videothoracoscopic thymectomy patients had shorter duration of chest tube drainage, lesser amount of drainage, shorter hospital stay and lesser visual analogue scale score.[14]
But even in this less radical approach, immunosuppressive medications (including corticosteroids) were not started until after operation.[12] We proposed that only addition of immunosuppressants like azothioprine and cyclosporine could cause increase in postoperative morbidity after transsternal procedures. Thus we chose not to start this medication in patients who are candidates of transsternal thymectomy. Corticosteroids were excluded from other immunosuppressants as far as complications are concerned. The other important issue is closure of sternotomy in osteoporotic patients. This problem could be solved by the use of modified Robicsek technique[4] in closure of sternums after complete and partial sternotomy when the sternum is osteoporotic due to prolonged corticosteroid therapy.
In an extended thymectomy series published recently[15] the team work of neurologist, thoracic surgeon and anaesthesist was emphasized to improve outcome and to decrease postoperative complications. In this study, the length of hospital stay and the rate of prolonged intubation was reported to be decreased after 1992. Pharmacological control of myasthenic symptoms and the presence of team work in the perioperative setting reduced the incidence of complications. We are supporting this study with fullheart. No complications were encountered including prolonged intubation in the last 25 patients, with an average of 5.6 days of hospital stay after transsternal procedures. It is believed that the approach to MG patients in perioperative period of thymectomy is getting better with the teams cooperation and increasing experience.
In conclusion; in this large series comprising more than two decades, we showed statistically significant relation between postoperative complications and subgroup of medications in patients who had thymectomy for myasthenia gravis. Patients who had cholinesterase inhibitors, immunosuppressive therapy with additional corticosteroids had increased number of complications. Thus we strongly advice to take additional precautions in this subset of patients to prevent complications after thymectomy for myasthenia gravis.
1) Drachman DB. Myasthenia gravis. N Engl J Med 1994;330:1797-810.
2) Parrillo JE, Fauci AS. Mechanisms of glucocorticoid action on immune processes. Annu Rev Pharmacol Toxicol 1979; 19:179-201.
3) Mulder DG. Extended transsternal thymectomy. Chest Surg Clin N Am 1996;6:95-105.
4) Robicsek F, Daugherty HK, Cook JW. The prevention and treatment of sternum separation following open-heart surgery. J Thorac Cardiovasc Surg 1977;73:267-8.
5) Seggia JC, Abreu P, Takatani M. Plasmapheresis as preparatory method for thymectomy in myasthenia gravis. Arq Neuropsiquiatr 1995;53(3-A):411-5.
6) Younger DS, Worrall BB, Penn AS. Myasthenia gravis: historical perspective and overview. Neurology 1997;48:S1-S7.
7) Machens A, Emskotter T, Busch C, Izbicki JR. Postoperative infection after transsternal thymectomy for myasthenia gravis: a retrospective analysis of 125 cases. Surg Today 1998;28:808-10.
8) Kas J, Kiss D, Simon V, Svastics E, Major L, Szobor A. Decade-long experience with surgical therapy of myasthenia gravis: early complications of 324 transsternal thymectomies. Ann Thorac Surg 2001;72:1691-7.
9) Mack MJ. Video-assisted thoracoscopy thymectomy for myasthenia gravis. Chest Surg Clin N Am 2001;11:389-405.
10) Meyers BF, Cooper JD. Transcervical thymectomy for myasthenia gravis. Chest Surg Clin N Am 2001;11:363-8.
11) Cooper JD, Al-Jilaihawa AN, Pearson FG, Humphrey JG, Humphrey HE. An improved technique to facilitate transcervical thymectomy for myasthenia gravis. Ann Thorac Surg 1988;45:242-7.
12) Bril V, Kojic J, Ilse WK, Cooper JD. Long-term clinical outcome after transcervical thymectomy for myasthenia gravis. Ann Thorac Surg 1998;65:1520-2.
13) Papatestas AE, Genkins G, Kornfeld P, Eisenkraft JB, Fagerstrom RP, Pozner J, et al. Effects of thymectomy in myasthenia gravis. Ann Surg 1987;206:79-88.