RESEARCH PAPER

Migraine headache associated with multiple
sclerosis: Results from the Nationwide Inpatient
Sample (NIS)

Sura S. Khuder a Sreekiran Thotakura b Fouzia Siddiqui b Nabeel A. Herial b Sadik A. Khuder c and Boyd
M. Koffman b

Corresponding author(s): boyd.koffman@utoledo.edu

aCollege of Medicine and Life Sciences, University of Toledo Toledo, OH 43614, USA,bDepartment of Neurology, University of Toledo, Toledo, OH 43606, USA, and
cDepartment of Medicine, University of Toledo, Toledo, OH 43614, USA.

Background: Multiple Sclerosis (MS) is a dysimmune process
that targets axons in the central nervous system. A high preva-
lence of migraine headache has been reported among MS pa-
tients. Objecctives: In this study, we investigated headache
prevalence and association in MS patients. Methods: The Health
Cost and Utilization Project (HCUP) Nationwide Inpatient Sam-
ple (NIS) data was utilized. MS hospitalizations ("cases") were
identified by ICD-9-CM code 340. Non-MS Hospitalizations ("con-
trols") were matched to cases 1:1 by age and gender. Results:
We identified 18955 MS patients between 2010 and 2013. The
prevalence of migraine among MS patients (7%) was significantly
higher than the control group (2.8%). Non-specified Migraine
constituted the highest percentages of migraine subtype in both
groups. All the subtypes of headache, except migraine without
aura, were significantly higher among MS patients compared to
the control group. Among MS patients, young age, obesity, de-
pression, chronic lung disease, white race, and female gender
were significant predictors of migraine. Conclusions: Our study
provides prevalence data for different subtypes of headache and
supports the association of young age, obesity, depression,
chronic lung disease, white race, and female gender as risk fac-
tors for migraine.

Multiple Sclerosis | autoimmune diseases | comorbidities |
HCUP data

Multiple sclerosis (MS) is a chronic inflammatory process thattargets myelinated axons in the central nervous system. MS
is an immune-mediated disease in which activated immune cells
invade the central nervous system and cause inflammation charac-
terized by myelin loss, varying degrees of axonal pathology, and
progressive neurological dysfunction. The clinical features of MS
encompass an extremely wide range of neurological symptoms (1).

The etiology of MS is not yet completely understood (2). A com-
plex interplay of genetic and environmental associated factors is
currently considered for the etiology of the disease (3, 4).

People with multiple sclerosis (MS) have an increased inci-
dence of headaches, although the comorbidity of headaches and
MS is poorly understood (5). Several studies suggest a high preva-
lence of headache among MS patients and with migraine represent-
ing the most common type of primary headache. The association
between migraine and MS was observed in two case-control series
(6, 7). A population-based study from Sicily reported a doubling
of headache prevalence in MS patients compared to controls (8).
Only one study did not detect a statistically significant difference in
headaches between MS patients and historical controls (9), possi-
bly due to very high prevalence of primary headaches in the local
population. In this study, we investigated the prevalence and risk
for migraine among patients with MS in the United States utilizing
a nationwide database.

Material and Methods

Data used in this study is from the Healthcare Cost and Uti-
lization Project (HCUP) sponsored by the Agency for Healthcare
Research and Quality (AHRQ). HCUP combines data from state

Submitted: 02/19/2020, published: 04/25/2021.

Freely available online through the UTJMS open access option

translation@utoledo.edu UTJMS 2021 Vol. 9 1–5

https://orcid.org/0000-0002-5036-7623
https://orcid.org/0000-0002-8815-0008
https://orcid.org/0000-0002-5790-783X
https://orcid.org/0000-0003-2673-6326
https://orcid.org/0000-0002-3757-5874
mailto:boyd.koffman@utoledo.edu


organizations, hospital associations, private data organizations, and
the Federal government to create a national information resource
consisting of patient-level health care data. The largest collection
of longitudinal hospital care data in the United States is included
in HCUP beginning in 1988. The HCUP database represents 96%
of the U.S. population and includes over 32 million observations.
HCUP consists of multiple databases, however the database used in
this study is the Nationwide Inpatient Sample (NIS) for the years
2010-2013. This database has inpatient data from over 1,000 hospi-
tals and up to 44 states in the United States.

Subjects included in the study consisted of individuals who
were at least 18 years of age and had an ICD-9-CM diagnosis code
(340) for MS. The NIS database allows up to 25 diagnoses per pa-
tient. Since MS is an immune-mediated process, controls were ex-
cluded if they had one or more of over 100 different autoimmune
disease ICD-9 diagnosis codes or were under the age of 18. MS
patients and controls were included and matched by age (± 5 years)
and sex. One control was matched to each MS patient (18955 MS
and 18955 Control).

The comorbid conditions used in this analysis totaled 29 and
were variables included in the NIS database obtained from the
AHRQ comorbidity software. This comorbidity software assigns
variables that identify comorbidities in discharge records using
ICD-9-CM codes. The 29 comorbidities included in this study are
listed in Table 4.

All statistical analyses were conducted using SAS version 9.2
(SAS Institute, Cary, NC) and R. Frequency distributions between
categorical variables were assessed using the χ 2 test. Logistic re-
gression models were utilized to compare patients with and without
MS for 29 different comorbidities. The survey logistic procedures in
R were used in this analysis to include the weight variable provided
in the database. We evaluated risk factors associated with headache
such as age, gender, race, smoking, alcohol, obesity, depression, and
comorbidities. Regarding race, other races ("other") served as the
reference to which Whites, Blacks, and Hispanics were compared.

Results

Between 2010 and 2013, there were 18955 admissions with
MS listed as principal diagnosis for admission. Comparisons of
MS patients and controls on demographic variables revealed equal
distributions for age, gender, and region (Table 1). Compared to
controls, there were significantly less admissions for Hispanic and
\other" among the MS group, and significantly increased admissions
among Blacks for the MS group.

The prevalence of migraine among MS patients (7%) was sig-
nificantly higher than the control group (2.8%). All the subtypes of
migraine were significantly higher among MS patients compared to
the control group (Table 2). Migraine unspecified constituted the
highest percentages of migraine in both groups. Migraine with and
without aura and unspecified were significantly higher among MS
patients compared to the control group.

Predictors of migraine headache among MS patients are pre-
sented in Table 3. The likelihood of migraine decreased as a func-
tion of age and is increased in females. Compared to the category

of "other", Whites were more likely to suffer from migraine. Co-
morbidities significantly increased the risk of migraine among MS
patients.

Table 4 presents the distribution comorbidities between mi-
graine and nonmigraine MS patients. Comorbidities that increase
the risk of migraine include chronic lung, depression, and obesity.
Comorbidities that decrease the risk of migraine include congestive
heart failure (CHF), hypertension, paralysis, and alcohol.

Table 1. Hospital admissions with migraine among MS and Con-
trols for 2010-2013.

Variable MS Control p-value
N=18955 N=18955

Age
(mean ± SD) 45.1 ± 13.5 45.0 ± 14.0 0.898

Gender
Female % 73.1 73.1 1

Race
Race White% 61.9 61.7 < 0.001

Black% 25.1 18.8
Hispanic% 9.2 12.6

Other% 3.8 6.9

Region
Northeast 24.2 23.8 0.748
Midwest 25.6 25.6

South 34.0 34.5
West 16.2 1 6.1

Comorbidities % 45.6 46.6 0.051

Smoking% 20.3 17.9 < 0.001

Table 2. Distribution of headache between MS and Controls.

Headache MS Controls p-value
N % N %

Migraine
With aura 36 0.2 15 0.1 0.0032

Without aura 44 0.2 16 0.1 < 0.0001
Hemiplegic,
Menstrual,

variant forms 48 0.3 33 0.2 0.2247
Unspecified 1196 6.3 462 2.4 < 0.0001

Total 1321 7.0 524 2.8 < 0.0001

2 translation@utoledo.edu Khuder SS et al.



Table 3. Predictors of Migraine headache among MS Patients.

Coefficient OR 95% CI p-value
Lower Upper

Age*
18-39 3.95 3.12 5.00 < 2e-16
40-59 2.82 2.26 3.53 < 2e-16

Female gender 3.48 2.88 4.21 < 2e-16

Race**
White 1.53 1.07 2.19 0.019
Black 1.11 0.77 1.61 0.567

Hispanic 1.18 0.79 1.76 0.410

Smoking 0.99 0.85 1.15 0.875

Comorbidities 1.32 1.16 1.49 < 0.0001

* Reference category (age): ≥ 60 years ** Reference category (race): Other.

Discussion

This study aimed to examine the prevalence of migraine among
MS patients based on hospital admissions data. Data suggests that
there is a statistically significant association between migraine and
MS, with MS patients being more than twice as likely to report mi-
graine as controls.

The prevalence of migraine among MS patient in this study
was 7%. This result is similar to those reported in other studies
(8-17). The results of the more recent studies based on Interna-
tional Headache Society criteria for diagnosis and classification of
headaches showed that the lifetime prevalence of migraine is higher
in MS patients (more than 50%) than in controls and general popu-
lation, suggesting an increased risk of migraine and a possible asso-
ciation between these two conditions.

Migraine prevalence decreased with age and this is consistent
with other studies. As headache prevalence rates decrease with age
(18) one could assume that the differences between MS patients
with and without migraine are due to the older age of the non-
migraine sufferers.

The higher prevalence of headache in women compared to men
has been attributed to the effect of female sex hormones. Epidemi-
ological studies consistently show higher prevalence of migraine in
women, with a female to male ratio in the order of 2.3:1 (18, 19).

Migraine prevalence was higher in Whites compared to Blacks
and this is consistent with those reported in the literature (20). Com-
pared to Asian and other races, the prevalence of migraine was

higher in Whites. Epidemiological studies have reported higher
prevalence in Caucasian as compared to Asian populations (21).

Among MS patients, individuals with migraine suffered from
depression at significantly higher rates than migraine-free counter-
part. This finding is consistent with previous literature data. Mi-
graine is reported as comorbid with depression in the general pop-
ulation (22) and also in the MS population (23). Moreover, depres-
sion was mentioned as a significant determinant of the severity of
comorbid migraine in multiple sclerosis (24).

MS migraineurs reported alcohol intake at significantly lower
rates than non-migraineur MS patients. Alcohol is mentioned as
one of many factors that can trigger migraine attacks (25). There-
fore, alcohol may be avoided not just by those with migraine. One
study observed that both those who experience migraine and those
who experience headache were likely to have low intake of alcohol
(26).

Obesity increased the risk of migraine among MS patients.
Obesity was mentioned as a risk factor for migraine in the litera-
ture, although migraine by itself was not more prevalent in obese pa-
tients. Obesity was also associated with the frequency and severity
of migraine (27), but the causal link between obesity and migraine
remains to be determined. Another study reported an association
between obesity and migraine that did not adjust for frequent intake
of acute pain drugs (28).

Our study has several important strengths. We used a na-
tional inpatient database representing 96% of the U.S. population
with over 32 million patient records utilized in analysis, enabling
a clearer picture of the prevalence of headache among MS patients
on a country-wide basis. Furthermore, the headache types identified
in this study are based on doctor-diagnosed diseases, and not self-

Khuder SS et al. UTJMS 2021 Vol. 9 3



Table 4. Distribution of comorbidities between Migraine and Non Migraine MS patients.

Migraine % Non p-value
Migrane %

Alcohol abuse 0.7 1.4 0.0380
Anemia:

deficiency anemias 10.1 9 0.1877
Rheumatoid arthritis and

collagen vascular diseases 2.6 1.9 0.0975
Chronic blood loss anemia 0.2 0.2 1

Congestive heart failure (CHF) 0.5 1.3 0.0101
Chronic pulmonary disease 17.8 11.0 < 0.0001

Coagulopathy 1.3 1.4 0.739
Depression 32.6 23.7 < 0.0001

Diabetes, uncomplicated 10.4 11.6 0.1929
Diabetes with complication 1.7 1.6 1

Drug abuse 5.2 4.8 0.5671
Hypertension 29.3 32.4 0.0202

Hypothyroidism 9.3 9.0 0.714
Liver disease 0.5 0.9 0.1621
Lymphoma 0.2 0.1 1

Fluid and electrolyte disorders 13.1 13.7 0.542
Metastatic cancer 0 0.1 0.3469

Other neurological disorders 0.1 0.1 1
Obesity 14.2 9.9 < 0.0001
Paralysis 9.0 10.9 0.03638

Peripheral vascular disorders 0.6 0.9 0.4195
Psychoses 9.1 7.4 0.03018

Pulmonary circulation disorders 0.2 0.4 0.3612
Renal Failure 0.9 1.3 0.248

Solid tumor without metastasis 0.2 0.3 0.8598
Peptic ulcer disease 0 0 1

Valvular disease 2.0 1.3 0.03985
Weight loss 1.5 2.3 0.09363

reporting by patients. In the case of autoimmune diseases, which
include rare diseases and diseases with considerable clinical hetero-
geneity and complex case definitions, the collection of data through
self-reporting involves a high probability of reporting bias.

There are also several potential weaknesses in the design of this
study. First, the data is limited to hospitalized patients, and therefore
not all patients suffering from multiple sclerosis were investigated.
However, the HCUP data may not reflect the true prevalence of mi-
graine. Furthermore, the group included in this study was sicker and
possibly showing higher prevalence of certain types of migraine.
Second, we were unable to adjust for significant covariates such as
family history, medication use, and diet. Third, multiple admission
for the same patient might be problematic. However, there is no
reason to believe that the pattern of admission is different between
MS patients and the controls. Moreover, we included only patients
admitted with MS as primary diagnosis.

Potential future directions:

1. The inpatient NIS database was used because it utilizes a
large population-based dataset, but MS is typically treated on an
outpatient basis. One potential extension of work may include find-
ing and exploiting a large population-based outpatient database to

more realistically model migraine in MS.

2. Is it possible that chronic CNS inflammation can present with
migraine-like symptoms but is actually an MS exacerbation? One
could argue that migraine and MS are both more prevalent in fe-
males and that migraine at MS presentation is simply a coincidence.
However, there is a literature suggesting that the initial presentation
of MS may include symptoms consistent with migraine. MS is an
immune-mediated disorder, and in one regard could be considered
a chronic encephalitis. Clinical recognition of new headache symp-
toms with features of migraine as an entity worthy of evaluation may
lead to earlier diagnosis of MS and potentially better outcomes with
earlier treatment. Another potential extension of work may include
seeking a database that allows linkage of subjects with medications,
diagnoses, durable medical equipment (DME) over time to evaluate
time course from diagnosis to use of DME such as cane, walker, or
wheelchair over time to evaluate the modification of symptoms with
treatment.

Conclusion

We conducted a large population-based case-control study eval-
uating the prevalence of migraine in MS cases compared to age- and
gender-matched controls. Migraine is common among patients with
MS; factors associated with increased likelihood of migraine in MS

4 translation@utoledo.edu Khuder SS et al.



include young age, obesity, depression, chronic lung disease, white
race, and female gender. Findings were similar in direction though
smaller in magnitude compared to previous studies which primarily
included much smaller numbers of MS cases. One immediate impli-
cation from this study is that potential risk factors that increase the
likelihood of migraine in MS (obesity, depression, and chronic lung
disease) should be modified when possible. Primary care providers,
psychiatrists, and neurologists are the clinicians in the best position
to modify these risk factors.

Conflict of interest

Authors declare no conflict of interest.

Institutional Review Board approval

Data sets from the Healthcare Cost and Utilization Project (H-
CUP) healthcare databases, including the Nationwide Inpatient Sur-
vey are deidentified and publicly/commercially available. These

data sets do not involve "human subjects" (as defined by federal
regulations and guidance). Therefore, their use requires neither IRB
review, an exempt determination, nor are users required to complete
the NIH human subjects training.

Authors’ contributions

SSK: data collection, data analysis, manuscript writing; ST:
data collection, data analysis, manuscript editing; FS: Study con-
cept and design, manuscript editing; NAH: Study concept and de-
sign, manuscript editing; SAK: Study concept and design; data col-
lection, project development, data analysis, manuscript editing and
content revision; BMK: Study concept and design, project devel-
opment, data analysis, manuscript writing; manuscript editing, and
content revision.

All authors read and approved the final document.

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