The Journal of Bone & Joint Surgery

The Journal of Bone & Joint Surgery, Volume 88, Issue 10

Scientific Articles | October 01, 2006

Superior Mesenteric Artery Syndrome Following Spinal Deformity Correction

Stuart V. Braun, MD¹; Douglas M. Hedden, MD, FRCSC²; Andrew W. Howard, MD, MSc, FRCSC³

¹ Stuart V. Braun, MD Department of Orthopaedics, Floating Hospital for Children, Tufts-New England Medical Center, 750 Washington Street, #206, Boston, MA 02111. E-mail address for S.V. Braun: sbraun@tufts-nemc.org
² Douglas M. Hedden, MD, FRCSC Stollery Children's Hospital, 2C3.65, WCM Centre, 8440 112 Street, Edmonton, AB T6G 2B7, Canada
³ Andrew W. Howard, MD, MSc, FRCSC Division of Orthopaedic Surgery, The Hospital for Sick Children, S107-555 University Avenue, Toronto, ON M5G 1X8, Canada

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The authors did not receive grants or outside funding in support of their research for or preparation of this manuscript. They did not receive payments or other benefits or a commitment or agreement to provide such benefits from a commercial entity. No commercial entity paid or directed, or agreed to pay or direct, any benefits to any research fund, foundation, educational institution, or other charitable or nonprofit organization with which the authors are affiliated or associated.

Investigation performed at The Hospital for Sick Children, Toronto, Ontario, Canada

The Journal of Bone and Joint Surgery, Incorporated

J Bone Joint Surg Am, 2006 Oct 01;88(10):2252-2257. doi: 10.2106/JBJS.E.00348

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Abstract

Background: Superior mesenteric artery syndrome is a known complication associated with the correction of spinal deformity. Recent investigations of this disorder have focused on patient height and weight. We are not aware of any published study examining the degree of deformity, type of curve, or magnitude of correction, and to our knowledge all of the reported literature on this syndrome lacks control data. The purpose of this study was to examine the relationship between the correction of spinal deformity and the development of superior mesenteric artery syndrome in patients with scoliosis. Our hypothesis was that greater correction of spinal deformity would increase the risk of the development of superior mesenteric artery syndrome.

Methods: A case-control study was performed over a five-year period. The primary outcome measure was the development of superior mesenteric artery syndrome. The predictor variables that were considered included demographic characteristics; preoperative height, weight, and body mass index; aspects of the deformity, including curve magnitude, Lenke curve classification, and correction; and operative factors, including surgical approach, estimated blood loss, and the presence of operative hypotension.

Results: A review of the records on 364 surgical procedures for scoliosis identified seventeen cases of superior mesenteric artery syndrome. Thirty-four subjects who had had surgery for scoliosis but no superior mesenteric artery syndrome were randomly selected as controls. Eight of the seventeen subjects with superior mesenteric artery syndrome had undergone a two-stage procedure (compared with one of the thirty-four controls, p < 0.001), nine of the seventeen had had combined anterior and posterior procedures (compared with two of the thirty-four controls, p < 0.001), and seven of the seventeen had had a thoracoplasty (compared with two of the thirty-four controls, p < 0.001). No significant differences were noted between the groups with regard to demographic factors. Compared with the controls, the patients in whom superior mesenteric artery syndrome developed were shorter (by a mean of 7.1 cm, p = 0.03), weighed less (by a mean of 11.5 kg, p = 0.001), had a lower body mass index (p = 0.003), had a greater minimal thoracic curve magnitude achieved by bending (a mean of 12° greater [45° for subjects with superior mesenteric artery syndrome and 33° for controls], p = 0.015), had a lower percent correction of the thoracic curve on bending (a mean of 11% lower, p = 0.025), and had more lumbar lateralization (88%, compared with 61% in the control group, had a Lenke lumbar modifier of B or C instead of A, p = 0.008). Multivariate logistic regression analysis identified a staged procedure (odds ratio, 31.0), the lumbar modifier (odds ratio, 9.06), body mass index (odds ratio, 7.75), and thoracic stiffness (odds ratio, 6.67) as the most predictive of the development of superior mesenteric artery syndrome.

Conclusions: Preoperative identification of the risk factors described above in conjunction with preoperative nutritional maximization should be considered in order to limit the prevalence of superior mesenteric artery syndrome in patients undergoing surgical correction of spinal deformity.

Level of Evidence: Therapeutic Level III. See Instructions to Authors for a complete description of levels of evidence.

Figures in this Article

Superior mesenteric artery syndrome is a known complication associated with the correction of spinal deformity^1-5. Recent studies of this disorder have focused on patient height and weight^3,4,6. To our knowledge, no investigator studying superior mesenteric artery syndrome in patients treated with scoliosis surgery has reported on the degree of spinal deformity, type of curve, or magnitude of correction, and all of the studies of superior mesenteric artery syndrome in this population have lacked control data.

Historically, superior mesenteric artery syndrome usually has been associated with scoliosis surgery, either with instrumentation or with application of a body cast. Death has been reported rarely⁷. There have been numerous case reports on patients with other causes of superior mesenteric artery syndrome, including hereditary motor and sensory neuropathy, AIDS, eating disorders, intravenous drug abuse, traumatic brain injury, and pregnancy^8-16.

The presumptive underlying common factor is a rapid change in body fat, resulting in the compression of the third portion of the duodenum between the superior mesenteric artery (the second branch of the abdominal aorta) and the spine^17,18. This compression of the duodenum causes an extrinsic partial or complete obstruction of the duodenum, resulting in bloating, abdominal discomfort, and vomiting. When superior mesenteric artery syndrome develops following scoliosis surgery, signs usually begin five to ten days postoperatively. Several radiographic studies have demonstrated this disorder^19-21. Secondary complications related to superior mesenteric artery syndrome potentially include delayed operative recovery, diminished nutritional recovery, poor wound-healing, and prolonged hospitalization. In some instances, surgical treatment has been advocated²², but it usually is not necessary.

The purpose of this study was to examine the relationship between correction of spinal deformity and the development of superior mesenteric artery syndrome. It was our hypothesis that greater correction of sagittal deformity would increase the risk of superior mesenteric artery syndrome. In addition, we tested other hypotheses with regard to height, weight, and body mass index as risk factors for the development of superior mesenteric artery syndrome.

Materials and Methods

Materials and Methods | Results | Discussion | Acknowledgements | References

After obtaining approval from our Ethics Board, we performed a case-control study of patients who had undergone correction of spinal deformity during a five-year period, from January 1999 through February 2004. Subjects in whom superior mesenteric artery syndrome had developed were identified from this group. A blinded observer randomly selected a control group of patients who had been treated with similar procedures by the same surgeons over the same time period but in whom superior mesenteric artery syndrome had not developed. No attempt was made to match these patients with regard to any outcome category.

Data with respect to preoperative and postoperative curve magnitudes were collected. Curves were classified according to the system of Lenke et al., with attention paid to both the coronal and the sagittal profile²³. In addition, the collected data included the preoperative and postoperative height and weight of the patient, the operative approach, whether the surgery was one-stage or two-stage, estimated blood loss, whether the patient had operative hypotension, and whether a thoracoplasty was performed.

Outcome Measures

The primary outcome measure was the prevalence of superior mesenteric artery syndrome. This syndrome was defined as prolonged postoperative nausea for more than one week and vomiting associated with an ileus, requiring supplemental nutrition. The diagnosis was confirmed in all subjects by radiographic findings indicating constriction of the third portion of the duodenum and delayed gastric emptying.

Predictor Variables

Standard radiographic assessment was performed with use of the Cobb method. All radiographs were made at a single institution with a standardized technique. One observer measured all radiographs. Radiographs made closest to the date of the surgery as well as those made between six and twelve months postoperatively were reviewed. Preoperative radiographs included full-length standing posteroanterior, lateral, and left-side and right-side bending views. Each curve was evaluated with respect to the percent correction on the preoperative bending radiograph and the postoperative correction. The percent correction on preoperative bending was defined as the degree to which a curve improved on a side-bending radiograph (standing curve magnitude minus side-bending curve magnitude divided by standing curve magnitude). Postoperative curve correction was defined as the degree to which the curve changed between the preoperative and postoperative radiographs (preoperative standing curve magnitude minus postoperative standing curve magnitude divided by preoperative standing curve magnitude). We also examined operative blood loss and episodes of operative hypotension as markers for potential hypoperfusion as a cause of superior mesenteric artery syndrome. Operative hypotension was defined as a mean arterial pressure of <50 mm Hg for more than thirty minutes.

Statistical Methods

A two-tailed Student t test with unequal variance was used to compare data and determine the significance of differences between the subjects with superior mesenteric artery syndrome and the control group. Chi-square analysis was used to examine the control and subject-group values with respect to curve type, operative approach, and whether the procedure was staged. The Fisher exact test was used when counts were small. Logistic regression analysis was performed with use of univariate analysis on all predictor variables. Multivariate logistic regression analysis was performed on predictors with a univariate p value of <0.10. Collinear variables were eliminated. From these predictors, a backward stepwise elimination was performed, with removal of the highest valued predictors until only variables with a p value of <0.10 remained in the model. Adjusted odds ratios were determined from the resulting predictors.

Results

Materials and Methods | Results | Discussion | Acknowledgements | References

We identified 364 patients who had undergone primary spinal deformity correction between January 1999 and February 2004. Superior mesenteric artery syndrome developed in seventeen (4.7%) of these patients. Fifteen of them had a diagnosis of adolescent idiopathic scoliosis, one had Marfan syndrome, and one had Duchenne muscular dystrophy. Two surgeons performed the spinal fusions with spinal instrumentation in all of the patients except one, who was treated by a third surgeon. A control group of thirty-four subjects was randomly chosen from the original group of 364 patients who had had scoliosis surgery. All of the control data were obtained from the two primary surgeons.

No significant differences were noted between the control and study groups with regard to demographic factors, including age, gender, or surgeon. The mean age at the time of the operation was fourteen years in the group in whom superior mesenteric artery syndrome developed and 14.4 years in the control group.

Preoperative height, weight, and body mass index all differed significantly between the two groups. On the average, the subjects with superior mesenteric artery syndrome were 7.1 cm shorter than the control subjects (p = 0.03), weighed 11.5 kg less (p = 0.001), and had a difference in the body mass index of 2.92 kg/m² (p = 0.003) (Table I).

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TABLE I Predictor Variables

	Mean and Standard Deviation
	Subjects with Mesenteric Artery Syndrome	Controls	P Value
Height (cm)	153.6 ± 14.3	160.7 ± 11.4	0.031
Weight (kg)	45.4 ± 10.8	56.8 ± 13.2	0.001
Preop. body mass index (kg/m²)	18.7 ± 3.1	21.7 ± 3.8	0.003
Lumbar curve
Cobb angle (deg)	45.0 ± 17.1	47.0 ± 15.8	0.43
Minimum curve on bending (deg)	18.0 ± 13.8	20.0 ± 16.9	0.39
Correction on bending (%)	57.4 ± 26.2	62.6 ± 22.8	0.25
Postop. curve (deg)	19.9 ± 8.9	19.0 ± 10.9	0.47
Postop. correction (%)	53.2 ± 22.5	59.0 ± 20.0	0.21
Thoracic curve
Cobb angle (deg)	67.0 ± 20.8	58.0 ± 12.8	0.060
Minimum curve on bending (deg)	45.0 ± 17.8	33.0 ± 12.6	0.015
Correction on bending (%)	33.0 ± 15.9	44.0 ± 17.6	0.025
Postop. curve (deg)	24.0 ± 11.1	22.0 ± 9.3	0.29
Postop. correction (%)	42.0 ± 14.7	35.0 ± 15.3	0.16
Proximal thoracic curve
Cobb angle (deg)	30.0 ± 14.8	25.0 ± 15.0	0.22
Minimum curve on bending (deg)	21.0 ± 16.3	16.0 ± 10.4	0.24
Correction on bending (%)	37.7 ± 25.2	48.0 ± 21.8	0.17
Postop. curve (deg)	14.0 ± 11.5	14.0 ± 8.6	0.45
Postop. correction (%)	15.0 ± 28.1	14.0 ± 30.0	0.34
Lordosis (T10-L2)
Preop. (deg)	6.0 ± 17.3	0.0 ± 17.2	0.13
Postop. (deg)	8.0 ± 5.6	5.0 ± 7.5	0.09
Postop. correction (%)	-2.0 ± 16.7	-5.0 ± 16.3	0.25
Kyphosis (T5-T10)
Preop. (deg)	31.0 ± 22.7	27.0 ± 13.3	0.24
Postop. (deg)	20.0 ± 8.1	22.0 ± 8.2	0.18
Postop. correction (%)	9.0 ± 20.5	3.0 ± 13.1	0.15
Estimated blood loss (mL)	1661.0 ± 1511.9	1315.0 ± 684.1	0.22

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TABLE I Predictor Variables

	Mean and Standard Deviation
	Subjects with Mesenteric Artery Syndrome	Controls	P Value
Height (cm)	153.6 ± 14.3	160.7 ± 11.4	0.031
Weight (kg)	45.4 ± 10.8	56.8 ± 13.2	0.001
Preop. body mass index (kg/m²)	18.7 ± 3.1	21.7 ± 3.8	0.003
Lumbar curve
Cobb angle (deg)	45.0 ± 17.1	47.0 ± 15.8	0.43
Minimum curve on bending (deg)	18.0 ± 13.8	20.0 ± 16.9	0.39
Correction on bending (%)	57.4 ± 26.2	62.6 ± 22.8	0.25
Postop. curve (deg)	19.9 ± 8.9	19.0 ± 10.9	0.47
Postop. correction (%)	53.2 ± 22.5	59.0 ± 20.0	0.21
Thoracic curve
Cobb angle (deg)	67.0 ± 20.8	58.0 ± 12.8	0.060
Minimum curve on bending (deg)	45.0 ± 17.8	33.0 ± 12.6	0.015
Correction on bending (%)	33.0 ± 15.9	44.0 ± 17.6	0.025
Postop. curve (deg)	24.0 ± 11.1	22.0 ± 9.3	0.29
Postop. correction (%)	42.0 ± 14.7	35.0 ± 15.3	0.16
Proximal thoracic curve
Cobb angle (deg)	30.0 ± 14.8	25.0 ± 15.0	0.22
Minimum curve on bending (deg)	21.0 ± 16.3	16.0 ± 10.4	0.24
Correction on bending (%)	37.7 ± 25.2	48.0 ± 21.8	0.17
Postop. curve (deg)	14.0 ± 11.5	14.0 ± 8.6	0.45
Postop. correction (%)	15.0 ± 28.1	14.0 ± 30.0	0.34
Lordosis (T10-L2)
Preop. (deg)	6.0 ± 17.3	0.0 ± 17.2	0.13
Postop. (deg)	8.0 ± 5.6	5.0 ± 7.5	0.09
Postop. correction (%)	-2.0 ± 16.7	-5.0 ± 16.3	0.25
Kyphosis (T5-T10)
Preop. (deg)	31.0 ± 22.7	27.0 ± 13.3	0.24
Postop. (deg)	20.0 ± 8.1	22.0 ± 8.2	0.18
Postop. correction (%)	9.0 ± 20.5	3.0 ± 13.1	0.15
Estimated blood loss (mL)	1661.0 ± 1511.9	1315.0 ± 684.1	0.22

Univariate logistic regression analysis was used to assess various aspects of the preoperative deformity. The patients in whom superior mesenteric artery syndrome developed tended to have a larger thoracic curve (p = 0.06), with a significantly greater minimal thoracic curve magnitude achieved by bending (a mean of 12° greater, p = 0.015) and significantly less correction of the thoracic curve on bending (a mean of 11% less, p = 0.025). The other preoperative curve values were not significantly different between groups, except for the lumbar modifier, which differed significantly between the subjects and controls (p < 0.001). No significant differences were noted between the patients with superior mesenteric artery syndrome and the controls with regard to the degree of postoperative deformity or correction (Table I).

The surgical approach (anterior, posterior, or combined), the number of surgical stages, and the use of thoracoplasty all differed significantly (p < 0.001) between the patients with superior mesenteric artery syndrome and the controls (Table II). With the numbers studied, no significant differences were noted between the two groups with respect to estimated blood loss or intraoperative episodes of hypotension.

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TABLE II Procedure Variables

	Subjects with Mesenteric Artery Syndrome	Controls	P Value
Approach			<0.001
Anterior fusion and instrumentation	0	3
Posterior fusion and instrumentation	8	29
Anterior and posterior fusion and instrumentation	9	2
No. of stages			<0.001
1	9	33
2	8	1
Thoracoplasty			<0.001
Yes	7	2
No	10	32

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TABLE II Procedure Variables

	Subjects with Mesenteric Artery Syndrome	Controls	P Value
Approach			<0.001
Anterior fusion and instrumentation	0	3
Posterior fusion and instrumentation	8	29
Anterior and posterior fusion and instrumentation	9	2
No. of stages			<0.001
1	9	33
2	8	1
Thoracoplasty			<0.001
Yes	7	2
No	10	32

A difference between the groups was noted with respect to classification of the preoperative deformity according to the system of Lenke et al.²³, with 88% of the patients with superior mesenteric artery syndrome having a type-B or C (rather than type-A) lumbar modifier (lumbar lateralization) compared with 61% of the controls (p < 0.001). We also noted a trend toward a higher percentage of patients with positive thoracic kyphosis in the group with superior mesenteric artery syndrome than in the control group (Table III).

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TABLE III Lenke Classification

	No. of Patients
	With Mesenteric Artery Syndrome	Controls	P Value
Curve type			0.17
1	11	16
2	4	3
3	0	3
4	0	1
5	0	3
6	2	2
Lumbar modifier			<0.001
A	2	11
B	8	4
C	7	13
Sagittal profile			0.07
Positive	4	4
Neutral	12	21
Negative	1	3

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TABLE III Lenke Classification

	No. of Patients
	With Mesenteric Artery Syndrome	Controls	P Value
Curve type			0.17
1	11	16
2	4	3
3	0	3
4	0	1
5	0	3
6	2	2
Lumbar modifier			<0.001
A	2	11
B	8	4
C	7	13
Sagittal profile			0.07
Positive	4	4
Neutral	12	21
Negative	1	3

After use of multivariate logistic regression analysis and backward stepwise elimination, four predictor variables remained: the lumbar modifier, the number of stages of the surgery, body mass index, and the stiffness of the thoracic curve (Table IV). Multivariate logistic regression analysis identified a staged procedure (odds ratio, 31.0), the lumbar modifier (odds ratio, 9.06), body mass index (odds ratio, 7.75), and thoracic stiffness (odds ratio, 6.67) as the most predictive of the development of superior mesenteric artery syndrome.

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TABLE IV Results of Multivariate Analysis

Variable	Coefficient	P Value
Lumbar modifier (B or C rather than A)	0.257	0.038309
Staged procedure or thoracoplasty or combined approach	-0.517	0.000460
Body mass index	0.042	0.019388
Percent correction of thoracic curve on bending	0.005	0.081904

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TABLE IV Results of Multivariate Analysis

Variable	Coefficient	P Value
Lumbar modifier (B or C rather than A)	0.257	0.038309
Staged procedure or thoracoplasty or combined approach	-0.517	0.000460
Body mass index	0.042	0.019388
Percent correction of thoracic curve on bending	0.005	0.081904

On the basis of the significant predictor variables identified in the multivariate logistic regression analysis, odds ratios were determined at various cut-off values. These thresholds were determined to maximize the odds ratios (Table V). Multivariate logistic regression analysis identified a staged procedure (odds ratio, 31.0), the lumbar modifier (odds ratio, 9.06), body mass index (odds ratio, 7.75), and thoracic stiffness (odds ratio, 6.67) as the most predictive of the development of superior mesenteric artery syndrome.

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TABLE V Odds Ratios

Variable	Odds Ratio	P Value
Body mass index <25th percentile for age	7.75	0.011
<60% correction of thoracic curve on bending	6.67	0.006
Lumbar modifier of A rather than B or C	9.06	0.0037
Two compared with one-stage procedure	31.0	<0.001
Thoracoplasty	13.13	0.0025
Combined anterior and posterior fusion compared with anterior or posterior fusion	21.86	<0.0001
Two-stage procedure or combined approach or thoracoplasty	21.43	<0.0001

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TABLE V Odds Ratios

Variable	Odds Ratio	P Value
Body mass index <25th percentile for age	7.75	0.011
<60% correction of thoracic curve on bending	6.67	0.006
Lumbar modifier of A rather than B or C	9.06	0.0037
Two compared with one-stage procedure	31.0	<0.001
Thoracoplasty	13.13	0.0025
Combined anterior and posterior fusion compared with anterior or posterior fusion	21.86	<0.0001
Two-stage procedure or combined approach or thoracoplasty	21.43	<0.0001

Discussion

Materials and Methods | Results | Discussion | Acknowledgements | References

There are potentially several factors at play in the development of superior mesenteric artery syndrome in patients undergoing surgical correction of a spinal deformity. We believe that we are the first to examine the magnitude of the spinal deformity and the Lenke classification as predictors of superior mesenteric artery syndrome and that we are the first to include a control group in the study of this syndrome in this population. Our purpose was to examine the relationship between spinal deformity correction and the development of superior mesenteric artery syndrome. We identified an overall prevalence of the syndrome of 4.7%. Our hypothesis that greater spinal deformity correction would increase the risk of superior mesenteric artery syndrome was only partially supported by our findings.

This study had some limitations as many factors can contribute to the development of superior mesenteric artery syndrome. By examining body morphology, in addition to intraoperative factors, we attempted to limit confounding factors. We included a control group to limit potential surgical and practice-environment-specific factors as additional confounding elements. Ideally, we would have limited our study to only adolescent idiopathic curves, but, because of the relatively low prevalence of the disorder, that could have weakened the significance of our results. If it were feasible, we could have also examined all 364 subjects who had undergone spinal fusion over the time frame. By randomly limiting our control group to approximately 10% of the whole group of patients who had undergone surgery for scoliosis, we could have inadvertently selected a control group that was not a true representative sample of the group as a whole. Despite these potential study limitations, several significant factors were identified.

Our findings with regard to preoperative patient weight and body mass index are consistent with those of other reports^4,7. Interestingly, our patients with superior mesenteric artery syndrome were shorter in addition to weighing less than the controls. Preoperative height (p = 0.03), weight (p = 0.001), and body mass index (p = 0.003) all differed significantly between the subjects with superior mesenteric artery syndrome and the controls.

The stiffness of the thoracic curve, as defined by a greater minimal thoracic curve magnitude achieved by bending (p = 0.015), and the Lenke lumbar modifier (p < 0.001) also differed significantly between the subjects with superior mesenteric artery syndrome and the controls. With the numbers studied, there were no significant differences between the groups with respect to the preoperative curve magnitude, the postoperative curve magnitude, or the percentage of surgical correction. We were unable to detect an association between the Lenke curve type and the development of superior mesenteric artery syndrome. The number of surgical stages (p < 0.001), the surgical approach (p < 0.001), and the performance of a thoracoplasty (p < 0.001) were also significantly different between the two groups. These elements of surgical technique are perhaps used more often in patients with stiffer curves, in that the anterior approach and staged procedures are commonly reserved for larger curves with less correction on preoperative bending radiographs. These findings all support the notion that patients with stiffer thoracic curves that have more lateralized lumbar apices are at a higher risk for the development of superior mesenteric artery syndrome. Perhaps translation of the lateralized apex of the lumbar spine along with the improvement of the lumbar hypolordosis leads to stretching of the superior mesenteric artery, which then compresses the duodenum.

The estimated operative blood loss and episodes of operative hypotension were not significantly different between the two patient groups, suggesting that the operative environment did not increase the risk of superior mesenteric artery syndrome developing through intraoperative hypoperfusion.

As a result of this study, in addition to assessing nutritional status and attempting to normalize body weight preoperatively, we routinely place jejunal feeding tubes at the first surgical procedure when we are performing staged spinal deformity correction.

In conclusion, patients with a body mass index that is in less than the twenty-fifth percentile for their age, those with a stiffer thoracic curve (<60% correction on bending radiographs), and those with a laterally displaced lumbar curve (Lenke B or C) are at higher risk for the development of superior mesenteric artery syndrome following correction of spinal deformity. Procedures in addition to posterior spinal fusion and instrumentation, including thoracoplasty, an anterior approach, and a staged operation, are also significantly associated with the development of superior mesenteric artery syndrome, although they are probably additional markers for curve stiffness. ?

Acknowledgements

Materials and Methods | Results | Discussion | Acknowledgements | References

Note: The authors thank the following people who were instrumental in the course of this research and the development of the manuscript: Benjamin Alman, William Cole, Glenda Courtney-Martin, Nicole Leeks, Unni Narayanan, Giles Pattison, Robert Salter, John Wedge, James Wright, and Colleen Kelly.

References

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body mass index procedure ; superior mesenteric artery syndrome ; spinal deformities

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Stuart V. Braun, Douglas M. Hedden, Andrew W. Howard; Superior Mesenteric Artery Syndrome Following Spinal Deformity Correction. The Journal of Bone & Joint Surgery. 2006 Oct;88(10):2252-2257.

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