related

Ventriculostomy related infection risk factors

Ventriculostomy related infection risk factors

Ventriculostomy related infection risk factors include prior brain surgerycerebrospinal fluid fistula, and insertion site dehiscence. Walek et al. from Rhode Island Hospital found no significant association between infection risk and duration of external ventricular drainage placement 1).

A total of 15 supposed influencing factors includes: age, age & sex interactions, coinfection, catheter insertion outside the hospital, catheter type, CSF leakage, CSF sampling frequency, diagnosis, duration of catheterization, ICP > 20 mmHg, irrigation, multiple catheter, neurosurgical operation, reduced CSF glucose at catheter insertion and sex 2).

In a large series of patients, ventriculostomy related infection (VRI) was associated with a longer ICU stay, but its presence did not influence survival. A longer duration of ventriculostomy catheter monitoring in patients with VRI might be due to an increased volume of drained CSF during infection. Risk factors associated with VRIs are SAH, IVH, craniotomy, and coinfection 3).

A retrospective cohort study strengthens a growing body of works suggesting the importance of inoculation of skin flora as a critical risk factor in ventriculostomy related infections, underscoring the importance of drain changes only when clinically indicated and, that as soon as clinically permitted, catheters should be removed 4).

Associated with a longer ICU stay, but its presence did not influence survival. A longer duration of ventriculostomy catheter monitoring in patients with VAI might be due to an increased volume of drained CSF during infection. Risk factors associated with VAIs are subarachnoid hemorrhage (SAH), intraventricular hemorrhage IVH, craniotomy, and coinfection 5).

The risk of infection increases with increasing duration of catheterization and with repeated insertions. The use of local antibiotic irrigation or systemic antibiotics does not appear to reduce the risk of VAI. Routine surveillance cultures of CSF were no more likely to detect infection than cultures obtained when clinically indicated. These findings need to be considered in infection control policies addressing this important issue 6).

An increased risk of infection has been observed in patients with subarachnoid or intraventricular hemorrhage, in patients with concurrent systemic infections as well as with longer duration of catheterization, cerebrospinal (CSF) leakage, and frequent manipulation of the EVD system 7) 8) 9).

Many studies have been conducted to identify risk factors of EVD-related infections. However, none of these risk factors could be confirmed in a cohort of patients. Furthermore they not show any difference in infection rates between patients who were placed in single- or multibed rooms, respectively 10).

Interestingly no risk factor for EVD-related infection could be identified in a retrospective single center study 11).

References

1)

Walek KW, Leary OP, Sastry R, Asaad WF, Walsh JM, Horoho J, Mermel LA. Risk factors and outcomes associated with external ventricular drain infections. Infect Control Hosp Epidemiol. 2022 Apr 26:1-8. doi: 10.1017/ice.2022.23. Epub ahead of print. PMID: 35471129.
2)

Sorinola A, Buki A, Sandor J, Czeiter E. Risk Factors of External Ventricular Drain Infection: Proposing a Model for Future Studies. Front Neurol. 2019 Mar 15;10:226. doi: 10.3389/fneur.2019.00226. eCollection 2019. Review. PubMed PMID: 30930840; PubMed Central PMCID: PMC6428739.
3)

Bota DP, Lefranc F, Vilallobos HR, Brimioulle S, Vincent JL. Ventriculostomy-related infections in critically ill patients: a 6-year experience. J Neurosurg. 2005 Sep;103(3):468-72. PubMed PMID: 16235679.
4)

Katzir M, Lefkowitz JJ, Ben-Reuven D, Fuchs SJ, Hussein K, Sviri G. Decreasing external ventricular drain related infection rates with duration-independent, clinically indicated criteria for drain revision: A retrospective study. World Neurosurg. 2019 Aug 2. pii: S1878-8750(19)32121-7. doi: 10.1016/j.wneu.2019.07.205. [Epub ahead of print] PubMed PMID: 31382072.
5)

Bota DP, Lefranc F, Vilallobos HR, Brimioulle S, Vincent JL. Ventriculostomy-related infections in critically ill patients: a 6-year experience. J Neurosurg. 2005 Sep;103(3):468-72. PubMed PMID: 16235679.
6)

Arabi Y, Memish ZA, Balkhy HH, Francis C, Ferayan A, Al Shimemeri A, Almuneef MA. Ventriculostomy-associated infections: incidence and risk factors. Am J Infect Control. 2005 Apr;33(3):137-43. PubMed PMID: 15798667.
7)

Camacho E. F., Boszczowski Í., Basso M., Jeng B. C. P., Freire M. P., Guimarães T., Teixeira M. J., Costa S. F. Infection rate and risk factors associated with infections related to external ventricular drain. Infection. 2011;39(1):47–51. doi: 10.1007/s15010-010-0073-5.
8)

Kim J.-H., Desai N. S., Ricci J., Stieg P. E., Rosengart A. J., Hrtl R., Fraser J. F. Factors contributing to ventriculostomy infection. World Neurosurgery. 2012;77(1):135–140. doi: 10.1016/j.wneu.2011.04.017.
9)

Mayhall C. G., Archer N. H., Lamb V. A., Spadora A. C., Baggett J. W., Ward J. D., Narayan R. K. Ventriculostomy-related infections. A positive epidemiologic study. The New England Journal of Medicine. 1984;310(9):553–559. doi: 10.1056/NEJM198403013100903.
10)

Hagel S, Bruns T, Pletz MW, Engel C, Kalff R, Ewald C. External Ventricular Drain Infections: Risk Factors and Outcome. Interdiscip Perspect Infect Dis. 2014;2014:708531. Epub 2014 Nov 17. PubMed PMID: 25484896; PubMed Central PMCID: PMC4251652.
11)

Hagel S, Bruns T, Pletz MW, Engel C, Kalff R, Ewald C. External ventricular drain infections: risk factors and outcome. Interdiscip Perspect Infect Dis. 2014;2014:708531. doi: 10.1155/2014/708531. Epub 2014 Nov 17. PubMed PMID: 25484896; PubMed Central PMCID: PMC4251652.

Trigeminal nerve-related pathology

Trigeminal nerve-related pathology

The trigeminal nerve (TGN) is the largest cranial nerve and can be involved in multiple inflammatory, compressive, ischemic, or other pathologies.

Trigeminal neuralgia

see Trigeminal neuralgia.

Postherpetic neuralgia

Postherpetic neuralgia in 20% of cases involves the trigeminal nerve (with a predilection for the ophthalmic division, called herpes zoster ophthalmicus).

Trigeminal trophic syndrome

Trigeminal trophic syndrome

Trigeminal neuropathy

see Trigeminal neuropathy.

Superior orbital fissure syndrome

Lesions in the cavernous sinus involve cranial nerves III, IV, VI, and V1 & V2 (ophthalmic and maxillary divisions of the trigeminal nerve), and spare II and V3.

Superior orbital fissure syndrome: dysfunction of nerves III, IV, VI and V1.

Orbital apex syndrome

Orbital apex syndrome: involves II, III, IV, VI and partial V1.

Raeder’s paratrigeminal neuralgia

Raeder’s paratrigeminal neuralgia.

Sturge-Weber syndrome

In Sturge-Weber syndrome: Ipsilateral port-wine facial nevus (nevus flammeus) usually in the distribution of 1st division of trigeminal nerve (forehead and/or eyelid) (rarely bilateral): not always present, alternatively sometimes in V2 or V3 regions 1).

Postoperative trigeminal nerve symptoms occur transiently in 22% and permanently in 11% following microsurgery, similar to the results of SRS 2).

Basilar impression: trigeminal nerve anesthesia.

In vestibular schwannoma or cerebellopontine angle meningioma, trigeminal nerve involvement may occur with tumors > 3 cm (check corneal reflex), with tic douloureux-like symptoms being unusual.

Osteopetrosis

Multiple sclerosis related trigeminal neuralgia treatment

Multiple sclerosis related trigeminal neuralgia treatment

The optimal treatment for medically refractory trigeminal neuralgia in multiple sclerosis (MS-TN) patients is unknown.

Surgical interventions are less effective for the treatment of MS-related TN compared with classic TN, and higher recurrence rates are observed and is more difficult to manage pharmacologically.

Treatment failure occurs in most of the MS-related TN patients independently of the type of treatment.

Lee et al. compared treatment outcomes between stereotactic radiosurgery (SRS) and radiofrequency ablation (RFA).

They performed a retrospective study of MS-TN patients treated with SRS or RFA between 2002 and 2019. Outcomes included degree of pain relief, pain recurrence, and sensory changes, segregated based on initial treatment, final treatment following retreatment with the same modality, and crossover patients.

Sixty surgical cases for 42 MS-TN patients were reviewed. Initial pain freedom outcomes and rates of retreatment were similar (SRS: 30%; RFA: 42%). RFA resulted in faster onset of pain freedom (RFA: <1 week; SRS: 15 weeks; p < 0.001). SRS patients with pain relief had longer intervals to pain recurrence at 2 years (p = 0.044). Final treatment outcomes favored RFA for pain freedom/off-medication outcomes (RFA: 44%; SRS: 11%; p = 0.031), though RFA resulted in more paresthesia (RFA: 81%; SRS: 39%; p = 0.012). Both provided at least 80% of adequate pain relief. Crossover patients did not have improved pain relief.

SRS and RFA are both valid surgical options for MS-TN. Discussion with providers will need to balance patient preference with their unique treatment characteristics 1).

Microvascular decompression

see Microvascular decompression for trigeminal neuralgia and multiple sclerosis.

Gamma Knife surgery

Between July 1992 and November 2010, 43 cases with more than 1 year of follow-up were operated with GKS for TN related to MS and prospectively evaluated in the Timone University Hospital, Marseille, France. Radiosurgery using the Gamma Knife (model B or C or Perfexion) was performed. A single 4-mm isocenter was positioned at a median distance of 8 mm (range 5.7-14.7) anterior to the emergence of the nerve. A median maximum dose of 85 Gy (range 75-90) was delivered. Results: The median follow-up period was 53.8 months (12-157.1). Thirty-nine patients (90.7%) were initially pain free. Their actuarial probability of remaining pain free without medication at 6 months, 1, 3, 5 and 10 years was 87.2, 71.8, 43.1, 38.3 and 20.5%, respectively, and remained stable till 12 years. The hypoesthesia actuarial rate at 6 months, 1 and 2 years was 11.5, 11.5 and 16%, and remained stable till 12 years. GKS proved safe and effective in this special group of patients 2).

Balloon compression

see Percutaneous balloon compression trigeminal rhizotomy for multiple sclerosis related trigeminal neuralgia.

References

1)

Lee AT, Raygor KP, Elefant F, et al. Comparison of Stereotactic Radiosurgery and Radiofrequency Ablation for Trigeminal Neuralgia in Multiple Sclerosis Patients [published online ahead of print, 2020 Sep 3]. Stereotact Funct Neurosurg. 2020;1-8. doi:10.1159/000509315
2)

Tuleasca C, Carron R, Resseguier N, Donnet A, Roussel P, Gaudart J, Levivier M, Régis J. Multiple Sclerosis-Related Trigeminal Neuralgia: A Prospective Series of 43 Patients Treated with Gamma Knife Surgery with More than One Year of Follow-Up. Stereotact Funct Neurosurg. 2014 Jul 8;92(4):203-210. [Epub ahead of print] PubMed PMID: 25011487.

Chiari related scoliosis

Chiari related scoliosis

Spinal deformity is an important clinical manifestation of Chiari type 1 deformity and syringomyelia.

Epidemiology

The prevalence of scoliosis in patients with Chiari Malformation and syringomyelia(CIM+SM) approaches 80% in some studies1) 2) 3) 4) 5).

Risk factors

Previous authors have suggested that risk factors for curve progression and spinal fusion include older age, the location of spinal deformity, extent of syrinx resolution, and degree of initial scoliosis 6) 7) 8) 9) 10) 11).

Syrinx characteristics, but not tonsil position, were related to the presence of scoliosis in patients with CM-I, and there was an independent association of syrinx length and holocord syrinx with scoliosis. Further study is needed to evaluate the nature of the relationship between syrinx and scoliosis in patients with CM-I 12).

Diagnosis

A challenge for physicians who see children with scoliosis is deciding when an MRI is warranted to look for neurological problems such as Chiari. Since scoliosis is not uncommon among adolescents, and because only a small percentage of those cases are actually related to Chiari, ordering an MRI for every child with scoliosis is not practical. In several studies, researchers have tried to find unique characteristics of Chiari related scoliosis which can alert doctors to when an MRI should be performed. Based on this work, some doctors recommend that Chiari should be checked for if there are any neurological signs and/or severe curves. Others have tried to focus on curve patterns that aren’t typically seen, for example certain types of double curves.

Outcome

The safety posterior spinal fusion and deformity correction in CIM+SM remains controversial and the outcomes are not well described 13) 14) 15) 16)17) 18).

Up to half of patients require spinal fusion despite neurosurgical intervention and nonoperative management 19) 20) 21) 22) 23).

While CIM+SM patients undergoing spine reconstruction can expect similar deformity corrections and outcomes scores to AIS patients, they also experience higher rates of neuromonitoring difficulties and neurological complications related to surgery. Surgeons should be prepared for these difficulties, particularly in children with larger syrinx size 24).

Case series

A large multicenter retrospective and prospective registry of pediatric patients with CM-I (tonsils ≥ 5 mm below the foramen magnum) and syrinx (≥ 3 mm in axial width) was reviewed for clinical and radiological characteristics of CM-I, syrinx, and scoliosis (coronal curve ≥ 10°).

Based on available imaging of patients with CM-I and syrinx, 260 of 825 patients (31%) had a clear diagnosis of scoliosis based on radiographs or coronal MRI. Forty-nine patients (5.9%) did not have scoliosis, and in 516 (63%) patients, a clear determination of the presence or absence of scoliosis could not be made. Comparison of patients with and those without a definite scoliosis diagnosis indicated that scoliosis was associated with wider syrinxes (8.7 vs 6.3 mm, OR 1.25, p < 0.001), longer syrinxes (10.3 vs 6.2 levels, OR 1.18, p < 0.001), syrinxes with their rostral extent located in the cervical spine (94% vs 80%, OR 3.91, p = 0.001), and holocord syrinxes (50% vs 16%, OR 5.61, p < 0.001). Multivariable regression analysis revealed syrinx length and the presence of holocord syrinx to be independent predictors of scoliosis in this patient cohort. Scoliosis was not associated with sex, age at CM-I diagnosis, tonsil position, pB-C2 distance (measured perpendicular distance from the ventral dura to a line drawn from the basion to the posterior-inferior aspect of C2), clivoaxial angle, or frontal-occipital horn ratio. Average curve magnitude was 29.9°, and 37.7% of patients had a left thoracic curve. Older age at CM-I or syrinx diagnosis (p < 0.0001) was associated with greater curve magnitude whereas there was no association between syrinx dimensions and curve magnitude.

Syrinx characteristics, but not tonsil position, were related to the presence of scoliosis in patients with CM-I, and there was an independent association of syrinx length and holocord syrinx with scoliosis. Further study is needed to evaluate the nature of the relationship between syrinx and scoliosis in patients with CM-I 25).

2018

Chotai et al. conducted a retrospective review at a single tertiary center for children undergoing Posterior fossa decompression (PFD) with untreated scoliosis, and identified 17 patients with complete follow-up data and imaging.

Overall, scoliosis improved in 7 (41.2%) patients, worsened in 9 (52.9%), and remained unchanged in 1 (5.9%) after PFD (mean follow-up of 7.8 ± 4.1 months). We found that 3 of the 8 (38%) children with early-onset scoliosis eventually needed scoliosis corrective surgery, which was needed in 7 of the 9 (78%) patients with adolescent-onset scoliosis. In addition, only 1 patient (17%) with a preoperative scoliosis curve <35 degrees and 9 patients (82%) with a curve ≥35 degrees required surgery for scoliosis correction despite PFD (p = 0.018).

In certain patients, PFD for CM-I may lead to improvement or stabilization of scoliosis 26).

2017

Previous reports have addressed the short-term response of patients with Chiari-related scoliosis (CRS) to suboccipital decompression and duraplasty (SODD); however, the long-term behavior of the curve has not been well defined.

Ravindra et al. undertook a longitudinal study of a cohort of patients who underwent SODD for CRS to determine whether there are factors related to Chiari malformation (CM) that predict long-term scoliotic curve behavior and need for deformity correction. METHODS The authors retrospectively reviewed cases in which patients underwent SODD for CRS during a 14-year period at a single center. Clinical (age, sex, and associated disorders/syndromes) and radiographic (CM type, tonsillar descent, pBC2 line, clival-axial angle [CXA], syrinx length and level, and initial Cobb angle) information was evaluated to identify associations with the primary outcome: delayed thoracolumbar fusion for progressive scoliosis. RESULTS Twenty-eight patients were identified, but 4 were lost to follow-up and 1 underwent fusion within a year. Among the remaining 23 patients, 11 required fusion surgery at an average of 88.3 ± 15.4 months after SODD, including 7 (30%) who needed fusion more than 5 years after SODD. On univariate analysis, a lower CXA (131.5° ± 4.8° vs 146.5° ± 4.6°, p = 0.034), pBC2 > 9 mm (64% vs 25%, p = 0.06), and higher initial Cobb angle (35.1° ± 3.6° vs 22.8° ± 4.0°, p = 0.035) were associated with the need for thoracolumbar fusion. Multivariable modeling revealed that lower CXA was independently associated with a need for delayed thoracolumbar fusion (OR 1.12, p = 0.0128).

This investigation demonstrates the long-term outcome and natural history of CRS after SODD. The durability of the effect of SODD on CRS and curve behavior is poor, with late curve progression occurring in 30% of patients. Factors associated with CRS progression include an initial pBC2 > 9 mm, lower CXA, and higher Cobb angle. Lower CXA was an independent predictor of delayed thoracolumbar fusion. Further study is necessary on a larger cohort of patients to fully elucidate this relationship 27).

2016

Mackel et al. conducted a multicenter retrospective review of 44 patients, aged 18 years or younger, diagnosed with Chiari I malformation and scoliosis who underwent posterior fossa decompression from 2000 to 2010. The outcome of interest was the need for spinal fusion after decompression. RESULTS Overall, 18 patients (40%) underwent posterior fossa decompression alone, and 26 patients (60%) required a spinal fusion after the decompression. The mean Cobb angle at presentation and the proportion of patients with curves > 35° differed between the decompression-only and fusion cohorts (30.7° ± 11.8° vs 52.1° ± 26.3°, p = 0.002; 5 of 18 vs 17 of 26, p = 0.031). An odds ratio of 1.0625 favoring a need for fusion was established for each 1° of increase in Cobb angle (p = 0.012, OR 1.0625, 95% CI 1.0135-1.1138). Among the 14 patients older than 10 years of age with a primary Cobb angle exceeding 35°, 13 (93%) ultimately required fusion. Patients with at least 1 year of follow-up whose curves progressed more 10° after decompression were younger than those without curve progression (6.1 ± 3.0 years vs 13.7 ± 3.2 years, p = 0.001, Mann-Whitney U-test). Left apical thoracic curves constituted a higher proportion of curves in the decompression-only group (8 of 16 vs 1 of 21, p = 0.002). CONCLUSIONS The need for fusion after posterior fossa decompression reflected the curve severity at clinical presentation. Patients presenting with curves measuring > 35°, as well as those greater than 10 years of age, may be at greater risk for requiring fusion after posterior fossa decompression, while patients less than 10 years of age may require routine monitoring for curve progression. Left apical thoracic curves may have a better response to Chiari malformation decompression 28).

2015

Strahle et al. sought to determine if there is an independent association between CM-I and scoliosis when controlling for syrinx status.

The medical records of 14,118 consecutive patients aged ≤ 18 years who underwent brain or cervical spine MRI at a single institution in an 11-year span were reviewed to identify patients with CM-I, scoliosis, and/or syrinx. The relationship between CM-I and scoliosis was analyzed by using multivariate regression analysis and controlling for age, sex, CM-I status, and syrinx status.

In this cohort, 509 patients had CM-I, 1740 patients had scoliosis, and 243 patients had a spinal syrinx. The presence of CM-I, the presence of syrinx, older age, and female sex were each significantly associated with scoliosis in the univariate analysis. In the multivariate regression analysis, older age (OR 1.02 [95% CI 1.01-1.03]; p < 0.0001), female sex (OR 1.71 [95% CI 1.54-1.90]; p < 0.0001), and syrinx (OR 9.08 [95% CI 6.82-12.10]; p < 0.0001) were each independently associated with scoliosis. CM-I was not independently associated with scoliosis when controlling for these other variables (OR 0.99 [95% CI 0.79-1.29]; p = 0.9).

A syrinx was independently associated with scoliosis in a large pediatric population undergoing MRI. CM-I was not independently associated with scoliosis when controlling for age, sex, and syrinx status. Because CM-I is not independently associated with scoliosis, scoliosis should not necessarily be considered a symptom of low cerebellar tonsil position in patients without a syrinx 29).

2013

A retrospective study was conducted on 22 patients with CMS who received brace treatment of scoliosis after PFD. Forty-four age- and sex-matched patients with idiopathic scoliosis (IS) who were treated with bracing served as the control group. The bracing outcome was considered a failure if the curve worsened 6° or more; otherwise, the treatment was considered to be successful.

The age and Risser sign were similar between patients with CMS and IS at brace initiation. The initial curve magnitude of patients with CMS(mean, 32.9° ± 6.3°; range, 20°-45°) was marginally significantly larger than that of patients with IS (mean, 29.6° ± 6.4°; range, 20°-45°). Until the final follow-up, a 6° or more worsening of the major curve occurred in 8 patients with CMS (36%) and in 15 patients with IS (34%). Overall, 7 patients with CMS (32%) and 13 patients with IS (30%) underwent spinal fusion surgery. No significant differences were observed between the 2 groups in the surgery rates or the bracing success rates (P > 0.05). In patients with CMS, neither the performance of syringosubarachnoid shunting nor the extent of tonsillar descent correlated with the bracing outcomes, whereas a double major curve pattern was found to be predictive for the failure of bracing.

Brace treatment subsequent to PFD is effective in preventing curve progression for 64% of patients with CMS, which is comparable with the rate that is observed in patients with IS. Double major curve pattern may be a risk factor in predicting treatment failure in patients with CMS 30).

Case reports

Tanaka et al. report the result of an 8-year follow-up of a 13-year-old girl with severe scoliosis associated with Chiari malformation and a large syringomyelia. The patient presented at the hospital at the age of 13 with a 68° scoliosis. Magnetic resonance imaging showed Chiari malformation and a large syringomyelia. Neurosurgical treatment involved foramen magnum decompression and partial C1 laminectomy, but the scoliosis still progressed.

They present the first case report of a rare course of scoliosis in a patient with CM-I and a large syringomyelia 31).

References

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Tubbs R, Beckman J, Naftel R, Chern J. Institutional experience with 500 cases of surgically treated pediatric Chiari malformation Type I. J Neurosurg Pediatr. 2011;7:248–56.
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Yeom JS, Lee C-K, Park K-W, et al. Scoliosis associated with syringomyelia: analysis of MRI and curve progression. Eur Spine J. 2007;16:1629–35.
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Phillips LH, Blanco JS, Sussman MD. Direct spinal stimulation for intraoperative monitoring during scoliosis surgery. Muscle & nerve. 1995;18:319–25.
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Farley Fa, Puryear A, Hall JM, Muraszko K. Curve progression in scoliosis associated with Chiari I malformation following suboccipital decompression. Journal of spinal disorders & techniques. 2002;15:410–4.
7)

Attenello FJ, McGirt MJ, Garcés-Ambrossi GL, Chaichana KL, Carson B, Jallo GI. Suboccipital decompression for Chiari I malformation: outcome comparison of duraplasty with expanded polytetrafluoroethylene dural substitute versus pericranial autograft. Childs Nerv Syst. 2009;25:183–90.
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Bhangoo R, Sgouros S. Scoliosis in children with Chiari I-related syringomyelia. Childs Nerv Syst. 2006;22:1154–7.
9)

Hwang SW, Samdani AF, Jea A, et al. Outcomes of Chiari I-associated scoliosis after intervention: a meta-analysis of the pediatric literature. Childs Nerv Syst. 2012
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Ozerdemoglu Ra, Transfeldt EE, Denis F. Value of treating primary causes of syrinx in scoliosis associated with syringomyelia. Spine. 2003;28:806–14.
11)

Sengupta DK, Dorgan J, Findlay GF. Can hindbrain decompression for syringomyelia lead to regression of scoliosis? Eur Spine J. 2000;9:198–201.
12) , 25)

Strahle JM, Taiwo R, Averill C, Torner J, Shannon CN, Bonfield CM, Tuite GF, Bethel-Anderson T, Rutlin J, Brockmeyer DL, Wellons JC, Leonard JR, Mangano FT, Johnston JM, Shah MN, Iskandar BJ, Tyler-Kabara EC, Daniels DJ, Jackson EM, Grant GA, Couture DE, Adelson PD, Alden TD, Aldana PR, Anderson RCE, Selden NR, Baird LC, Bierbrauer K, Chern JJ, Whitehead WE, Ellenbogen RG, Fuchs HE, Guillaume DJ, Hankinson TC, Iantosca MR, Oakes WJ, Keating RF, Khan NR, Muhlbauer MS, McComb JG, Menezes AH, Ragheb J, Smith JL, Maher CO, Greene S, Kelly M, O’Neill BR, Krieger MD, Tamber M, Durham SR, Olavarria G, Stone SSD, Kaufman BA, Heuer GG, Bauer DF, Albert G, Greenfield JP, Wait SD, Van Poppel MD, Eskandari R, Mapstone T, Shimony JS, Dacey RG, Smyth MD, Park TS, Limbrick DD. Radiological and clinical predictors of scoliosis in patients with Chiari malformation type I and spinal cord syrinx from the Park-Reeves Syringomyelia Research Consortium. J Neurosurg Pediatr. 2019 Aug 16:1-8. doi: 10.3171/2019.5.PEDS18527. [Epub ahead of print] PubMed PMID: 31419800.
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Huebert HT, MacKinnon WB. Syringomyelia and scoliosis. The Journal of bone and joint surgery British volume. 1969;51:338–43.
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Zhang H-Q, Deng A, Liu S-H, et al. Adult thoracolumbar or lumbar scoliosis with Chiari malformation and syringomyelia: a retrospective study of correction and fusion strategies. Archives of orthopaedic and trauma surgery. 2011;131:475–80.
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Bradley LJ, Ratahi ED, Crawford Ha, Barnes MJ. The outcomes of scoliosis surgery in patients with syringomyelia. Spine. 2007;32:2327–33.
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Ferguson RL, Devine J, Stasikelis P, Caskey P, Allen BL. Outcomes in Surgical Treatment of “ Idiopathic-Like ” Scoliosis Associated With Syringomyelia. Journal of spinal disorders & techniques. 2002;15:301–6.
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Godzik J, Holekamp TF, Limbrick DD, Lenke LG, Park TS, Ray WZ, Bridwell KH, Kelly MP. Risks and outcomes of spinal deformity surgery in Chiari malformation, Type 1, with syringomyelia versus adolescent idiopathic scoliosis. Spine J. 2015 Sep 1;15(9):2002-8. doi: 10.1016/j.spinee.2015.04.048. Epub 2015 May 7. PubMed PMID: 25959792; PubMed Central PMCID: PMC4550545.
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Chotai S, Basem J, Gannon S, Dewan M, Shannon CN, Wellons JC, Bonfield CM. Effect of Posterior Fossa Decompression for Chiari Malformation-I on Scoliosis. Pediatr Neurosurg. 2018 Jan 4. doi: 10.1159/000485254. [Epub ahead of print] PubMed PMID: 29298440.
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Ravindra VM, Onwuzulike K, Heller RS, Quigley R, Smith J, Dailey AT, Brockmeyer DL. Chiari-related scoliosis: a single-center experience with long-term radiographic follow-up and relationship to deformity correction. J Neurosurg Pediatr. 2017 Nov 24:1-5. doi: 10.3171/2017.8.PEDS17318. [Epub ahead of print] PubMed PMID: 29171800.
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Mackel CE, Cahill PJ, Roguski M, Samdani AF, Sugrue PA, Kawakami N, Sturm PF, Pahys JM, Betz RR, El-Hawary R, Hwang SW. Factors associated with spinal fusion after posterior fossa decompression in pediatric patients with Chiari I malformation and scoliosis. J Neurosurg Pediatr. 2016 Dec;25(6):737-743. Epub 2016 Sep 2. PubMed PMID: 27589598.
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Strahle J, Smith BW, Martinez M, Bapuraj JR, Muraszko KM, Garton HJ, Maher CO. The association between Chiari malformation Type I, spinal syrinx, and scoliosis. J Neurosurg Pediatr. 2015 Jun;15(6):607-11. doi: 10.3171/2014.11.PEDS14135. Epub 2015 Mar 13. PubMed PMID: 26030330.
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Sha S, Zhu Z, Sun X, Zheng X, Liu Z, Wu T, Yan H, Qiu Y. Effectiveness of brace treatment of Chiari malformation-associated scoliosis after posterior fossa decompression: a comparison with idiopathic scoliosis. Spine (Phila Pa 1976). 2013 Mar 1;38(5):E299-305. doi: 10.1097/BRS.0b013e318281dba6. PubMed PMID: 23238491.
31)

Tanaka M, Sugimoto Y, Arataki S, Takigawa T, Ozaki T. A rare course of scoliosis associated with Chiari malformation and syringomyelia. Acta Med Okayama. 2014;68(5):303-6. PubMed PMID: 25338487.

Factors Related to the Primary Discectomy in Recurrent Lumbar Disc Herniation

Factors Related to the Primary Discectomy in Recurrent Lumbar Disc Herniation

The degree of disc removal did not influence the outcome or complication rate in Fountas et al., clinical series 1)

For Carragee et al., the more aggressive removal of remaining intervertebral disc material may decrease the risk of reherniation, but the overall outcome was less satisfactory, especially during the first year after surgery 2).

McGirt et al., found that larger annulus defects and smaller percentage of disc removed during primary surgery, rather than absolute volume as reported in previous studies, were associated with an increased risk of recurrent lumbar disc herniation while more aggressive removal contributed to accelerated disc height loss 3).

systematic review of the literature suggests that conservative discectomy may result in shorter operative time, quicker return to work, and a decreased incidence of long-term recurrent low back pain but with an increased incidence of recurrent disc herniation. Prospective randomized trails are needed to firmly assess this possible benefit. 4).

The question remains how to balance the desire for maintaining disc height with minimizing the risk for reherniation 5).

References

 
1) 
Fountas KN, Kapsalaki EZ, Feltes CH, et al. Correlation of the amount of disc removed in a lumbar microdiscectomy with long-term outcome. Spine (Phila Pa 1976). 2004;29:2521–2526.
2) 
Carragee EJ, Spinnickie AO, Alamin TF, Paragioudakis S. A prospective controlled study of limited versus subtotal posterior discectomy: short-term outcomes in patients with herniated lumber intervertebral discs and large posterior anular defect. Spine (Phila Pa 1976). 2006;31:653–657.
3) 
McGirt MJ, Eustacchio S, Varga P, et al. A prospective cohort study of close interval computed tomography and magnetic resonance imaging after primary lumbar discectomy: factors associated with recurrent disc herniation and disc height loss. Spine (Phila Pa 1976). 2009;34:2044–2051.
4) 
Walters WC, 3rd, McGirt MJ. An evidence-based review of the literature on the consequences of conservative versus aggressive discectomy for the treatment of primary disc herniation with radiculopathy. Spine J. 2009;9:240–257.
5) 
Shepard N, Cho W. Recurrent Lumbar Disc Herniation: A Review. Global Spine J. 2019 Apr;9(2):202-209. doi: 10.1177/2192568217745063. Epub 2017 Dec 18. Review. PubMed PMID: 30984501; PubMed Central PMCID: PMC6448208.

Niedermeyer's Electroencephalography: Basic Principles, Clinical Applications, and Related Fields

Niedermeyer’s Electroencephalography: Basic Principles, Clinical Applications, and Related Fields


List Price: $272.54
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Niedermeyer’s Electroencephalography: Basic Principles, Clinical Applications, and Related Fields, Seventh Edition keeps the clinical neurophysiologist on the forefront of medical advancements. This authoritative text covers basic neurophysiology, neuroanatomy, and neuroimaging to provide a better understanding of clinical neurophysiological findings. This edition further delves into current state-of-the-art recording EEG activity both in the normal clinical environment and unique situations such as the intensive care unit, operating rooms, and epilepsy monitoring suites. As computer technology evolves, so does the integration of analytical methods that significantly affect the reader’s interpretations of waveforms and trends that are occurring on long-term monitoring sessions.
Compiled and edited by Donald L. Schomer and Fernando H. Lopes da Silva, along with a global team of experts, they collectively bring insight to crucial sections including basic principles of EEG and MEG, normal EEG, EEG in a clinical setting, clinical EEG in seizures and epilepsy, complementary and special techniques, event-related EEG phenomena, and shed light on the future of EEG and clinical neurophysiology. Akin to an encyclopedia of everything EEG, this comprehensive work is perfect for neurophysiology fellows, as well as neurology, neurosurgery, and general medical residents, and for the interns and medical students, and is a one-stop-shop for anyone training in EEG or preparing for neurophysiology or epilepsy board exams.

Book: Atlas of the Facial Nerve and Related Structures

Atlas of the Facial Nerve and Related Structures

By Nobutaka Yoshioka, Albert L. Rhoton

Atlas of the Facial Nerve and Related Structures

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Nobutaka Yoshioka, MD, PhD and Albert L. Rhoton Jr., MD have created an anatomical atlas of astounding precision. An unparalleled teaching tool, this atlas opens a unique window into the anatomical intricacies of complex facial nerves and related structures.
An internationally renowned author, educator, brain anatomist, and neurosurgeon, Dr. Rhoton is regarded by colleagues as one of the fathers of modern microscopic neurosurgery. Dr. Yoshioka, an esteemed craniofacial reconstructive surgeon in Japan, mastered this precise dissection technique while undertaking a fellowship at Dr. Rhotons microanatomy lab, writing in the preface that within such precision images lies potential for surgical innovation.
Special Features:

  • Includes a pair of 3D glasses to view the extraordinary images that are available online in the Thieme MediaCenter
  • Exquisite color photographs, prepared from carefully dissected latex injected cadavers, reveal anatomy layer by layer, with remarkable detail and clarity
  • Major sections include intracranial region and skull, upper facial and midfacial region, and lower facial and posterolateral neck region

Organized by region, each layered dissection elucidates specific nerves and structures with pinpoint accuracy, providing the clinician with in-depth anatomical insights. Precise clinical explanations accompany each photograph. In tandem, the images and text provide an excellent foundation for understanding the nerves and structures impacted by neurosurgical-related pathologies as well as other conditions and injuries.
An exceptionally stunning anatomical reference, this book is a must-have reference for residents, and advanced clinicians specializing in neurosurgery, facial plastic surgery, otolaryngology, maxillofacial surgery, and craniofacial surgery.

Product Details

  • Original language: English
  • Number of items: 1
  • Dimensions: .0″ h x .0″ w x .0″ l, .0 pounds
  • Binding: Hardcover
  • 128 pages