Highlights
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• Left-sided motor and sensory symptoms are more frequently associated with negative DWI in patients suspected of minor strokes.
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• This finding might be attributed to a distinct body representation and emotional processing of the right hemisphere.
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• Further studies are needed to replicate these findings and elucidate the underlying mechanisms
Introduction
Functional neurological disorder (FND) is an umbrella term encompassing several neurological manifestations in which the primary pathophysiological process is a functional, rather than structural, alteration of brain networks. Reference Hallett, Aybek, Dworetzky, McWhirter, Staab and Stone1 Historically, functional motor or sensory symptoms have been observed more frequently associated with the left side of the body. Reference Stern2,Reference Stone, Sharpe and Carson3 This phenomenon has been attributed to a distinct body representation and emotional processing of the right hemisphere and a possible “advantage” in the involvement of the non-dominant side. Reference Stern2,Reference Stone, Sharpe and Carson3 However, contradictory results have emerged from subsequent studies published over two decades ago. Reference Stern2–Reference Roelofs, Näring, Moene and Hoogduin4 These studies had several limitations, such as small sample sizes, reporting biases and, most importantly, lack of neuroimaging. Reference Stern2–Reference Roelofs, Näring, Moene and Hoogduin4 Therefore, whether there is a laterality preference for functional neurological manifestations remains unclear.
Minor stroke is a subtype of cerebrovascular event characterized by a small cerebral infarct. Reference Coutts5 More than half of patients initially suspected of having a minor stroke have a final diagnosis of stroke mimic – a condition presenting with stroke-like symptoms but with a nonvascular etiology. Reference Prabhakaran, Silver, Warrior, McClenathan and Lee6,Reference Moulin and Leys7 FNDs account for about one-third of stroke mimics. Reference Keselman, Cooray and Vanhooren8 The identification of a brain diffusion-weighted imaging (DWI)-positive lesion is the most reliable indicator of a vascular etiology. Reference Hurford, Li, Lovett, Kubiak, Kuker and Rothwell9,Reference Coutts, Moreau and Asdaghi10 Therefore, patients suspected of having an acute minor stroke represent a suitable population to assess the right hemisphere preference of functional disorders, as DWI provides an objective criterion to support the exclusion of an underlying functional etiology.
We aimed to investigate whether patients with unilateral left hemiparesis and/or hemisensory symptoms (implicating the right hemisphere) suspected of having a minor stroke are more likely to be associated with negative DWI compared to those with right hemiparesis and/or hemisensory symptoms (left hemisphere).
Methods
Standard protocol, approvals, registrations and patient consents
Ethics approval was obtained from the relevant ethics committees at all participating centers, and regulatory approval was obtained as necessary. Written informed consent was provided by patients or their authorized representatives.
Patient sample
Data are from the SpecTRA (Spectrometry for Transient Ischemic Attack Rapid Assessment), a multicenter, prospective, observational study that included patients with suspected transient ischemic attack (TIA) or minor stroke between December 2013 and March 2017. The ethics boards at each participating site approved the studies. The methodology and inclusion criteria of the studies have been previously published. Reference Joundi, Yu and Smith11,Reference Penn, Bibok and Saly12 In brief, SpecTRA included patients with mild acute neurological deficit (National Institute of Health Stroke Scale ≤ 3) and referral for neurological examination within 24 hours from symptom onset. Patients with transient monocular blindness or retinal artery occlusion were excluded. All patients were evaluated with either a brain MRI within seven days of the event or a CT and CT angiography within 24 hours. According to local standard protocols, patients were investigated with brain MRI at 1.5 or 3.0 T. A DWI-positive lesion was defined as any region of restricted diffusion consistent with acute ischemic stroke, regardless of anatomical consistency with clinical symptoms. MRIs were completed with 3 mm slice thickness with no gap and were reviewed by a neuroradiologist who was blind to clinical information. Demographics, relevant medical history and baseline clinical features at presentation were collected in each study.
Patients with (i) persistent unilateral motor or sensory symptoms, either in isolation or combined, and (ii) available follow-up DWI MRI were included. Patients with bilateral motor or sensory symptoms, discordant motor and sensory symptoms (i.e., right sensory and left motor symptoms) or symptoms that had resolved at the first neurological examination (time-based TIA) were excluded. Patients with suspected TIA were excluded from this analysis due to the unclear prevalence of FNDs presenting as brief transient episodes and the anticipated higher prevalence of negative DWI in this population.
Assessment of clinical subgroups
Patients were categorized as either having left hemiparesis and/or hemisensory symptoms (right hemisphere) or right hemiparesis and/or hemisensory symptoms (left hemisphere). For further analyses, patients with hemiparesis (± hemisensory) were classified as left and right hemiparesis groups, and patients with hemisensory symptoms (± hemiparesis) were classified as left and right hemisensory groups. Whenever we mention laterality in the results section, we are referring to the side of the symptoms rather than the hemisphere involved (left-sided symptoms vs. right-sided symptoms). Although brainstem stroke can rarely present with ipsilateral symptoms or a negative DWI, we do not expect these occurrences to significantly affect the analysis due to their anticipated low prevalence. Reference Salerno, Strambo, Nannoni, Dunet and Michel13
Outcome
The primary outcome was the proportion of patients with a negative DWI.
Statistical analysis
Continuous variables were presented as medians and interquartile ranges, while categorical variables were reported as counts and percentages. Demographics, medical history and baseline clinical features were compared between patients with left-sided and right-sided symptoms. Univariable comparisons were conducted using Fisher’s exact test for categorical variables and the Wilcoxon rank-sum test for continuous variables. To assess the association between left-sided and right-sided symptoms and negative DWI, we calculated the risk ratio (RR) with a 95% confidence interval (CI) after constructing a 2 × 2 contingency table. All analyses were also conducted for patients with motor (left vs. right) and sensory (left vs. right) symptoms. Due to the hypothesis-generating nature of the study, all analyses were considered exploratory and not adjusted for potential confounders.
Since younger age and female sex are associated with an increased risk of developing FNDs, Reference Aybek and Perez14,Reference Espay, Aybek and Carson15 we assessed whether the relationship between the symptoms side and the outcome was modified by age or sex by including a two-by-two multiplication interaction term (symptoms side × age) (symptoms side × sex) in generalized linear models. Then, we evaluated the significance of the potential effect modification with the pinteraction term. In case of no significant interaction, we provided adjusted estimates of effect using a generalized linear model adjusted for age and sex.
Statistical analyses were performed with Stata (Version 18.0), with all calculated P-values two-tailed and a conventional alpha level of 0.05. Associations were considered statistically significant when the 95% CI did not cross the 1.00 value.
Results
Patient characteristics
Among 1731 enrolled in SpecTRA, 774 patients were excluded due to resolved symptoms at the first neurological examination (suspected TIA), 326 were excluded due to the absence of strictly unilateral motor or sensory symptoms, and 47 were excluded because they were not investigated with acute MRI (Figure 1). Therefore, 584 (30.8%) were included in the final study sample, and their demographics, medical history and baseline clinical features are summarized in Table 1. Overall, 310 (53.1%) patients presented with left-sided symptoms and 274 (46.9%) with right-sided symptoms. Compared to patients with right-sided symptoms, patients who presented with left-sided symptoms were younger (67.1 [IQR = 56–77] years vs. 69.8 [IQR = 60–80] years, p = 0.042), exhibited a lower prevalence of arterial hypertension (51.6% [n = 150] vs. 62% [n = 170], p = 0.012) and coronary artery disease (8.7% [n = 27] vs. 15.3% [n = 42], p = 0.015) and experienced hemisensory symptoms more frequently (66.5% [n = 206] vs. 55.5% [n = 152], p = 0.008).
Figure 1. Flowchart of included patients. TIA = transient ischemic attack.
Table 1. Comparison of demographics, medical history, baseline clinical features and outcomes between left and right groups
IQR = interquartile interval.
Association between symptoms laterality and outcomes
Overall, 214 (36.6%) patients had a negative DWI. Among patients with negative DWI, 126 (58.9%) presented with left-sided symptoms and 88 (41.1%) with right-sided symptoms (p = 0.039) (Figure 2). There was a significant association between left-sided symptoms and negative DWI: RR 1.27 (95% CI = 1.02–1.57) (Table 2). Among the 370 patients with a positive DWI, 184 (49.7%) presented with left-sided symptoms and 186 (50.3%) with right-sided symptoms. Results were similar in a sensitivity analysis where patients with aphasia at baseline were excluded (Supplementary Material 1).
Figure 2. Distribution of laterality in patients with negative diffusion-weighted MRI in the full cohort (A), the subgroup with hemiparesis (B) and the subgroup with hemisensory symptoms (C). DWI = diffusion-weighted imaging.
Table 2. Left symptoms and association with negative DWI
DWI = diffusion-weighted imaging; RR = risk ratio; CI = confidence interval.
Subgroup analyses in motor and sensory symptoms
In the subgroup with hemiparesis (n = 468), 149 (31.8%) had a negative DWI. Among them, 89 (59.7%) presented with left-sided hemiparesis and 60 (40.3%) with right-sided hemiparesis (p = 0.013) (Figure 2). There was a significant association between left-sided hemiparesis and negative DWI: RR 1.42 (95% CI = 1.08–1.87) (Table 2).
In the subgroup with hemisensory symptoms (n = 358), 155 (43.3%) had a negative DWI. Among them, 93 (60%) presented with left-sided hemisensory symptoms and 62 (40%) with right-sided hemisensory symptoms (p = 0.451) (Figure 2). There was no significant association between left-sided hemisensory symptoms and negative DWI: RR 1.11 (95% CI = 0.87–1.41) (Table 2).
Effect of age and sex on the association between symptom laterality and DWI negativity
The estimated probability of negative DWI decreased steadily with advancing age (OR 0.98 [95% CI = 0.97–0.99] per 1-year increase), yet there was no interaction effect between age and the outcome concerning left or right symptoms (pinteraction = 0.787) (Figure 3).
Figure 3. Predicted probability of negative diffusion-weighted imaging as a function of age in patients with left versus right symptoms. DWI = diffusion-weighted imaging.
In females (n = 258), 121 (46.9%) had a negative DWI. Among them, 73 (60.3%) presented with left-sided symptoms and 48 (39.7%) with right-sided symptoms (p = 0.132). In males (n = 326), 93 (28.5%) had a negative DWI. Among them, 53 (57%) presented with left-sided symptoms, and 40 (43%) with right-sided symptoms (p = 0.222). There was no interaction effect between sex and the outcome concerning left-sided or right-sided symptoms (pinteraction = 0.057). After adjustments for age and sex, there was no association between left-sided symptoms and negative DWI (RR 1.16 (95% CI = 0.95–1.43).
Discussion
In our study, unilateral acute left-sided hemiparesis and/or hemisensory symptoms, compared with right-sided symptoms, were more frequently associated with negative DWI in a population of suspected minor strokes, showing an increased probability of approximately one-third. These findings were mainly driven by the presence of motor symptoms and were consistent across different ages and sexes.
In our study sample, the proportion of patients presenting with acute left-sided symptoms was slightly higher than those with right-sided symptoms (∼53% vs. ∼47%). While previous studies have shown a higher overall prevalence of right-sided symptoms among stroke patients, Reference Foerch, Misselwitz, Sitzer, Berger, Steinmetz and Neumann-Haefelin16,Reference Portegies, Selwaness, Hofman, Koudstaal, Vernooij and Ikram17 an opposite trend has been observed in the distinctive subgroup of minor strokes. Reference Mendelson and Prabhakaran18,Reference Coutts, Ankolekar and Appireddy19 These findings can be explained by the higher clinical eloquence of the left hemisphere, which facilitates diagnosis (high prevalence overall) but, at the same time, translates into greater clinical severity (low prevalence in the minor stroke subgroup). Reference Mendelson and Prabhakaran18,Reference Menezes, Ay and Wang Zhu20,Reference Güntürkün, Ströckens and Ocklenburg21 However, in our study, the proportion of patients with positive DWI was equally balanced (∼50%), in contrast with the proportion with negative DWI (∼60% vs. ∼40%). This supports the concept that the difference we observed in symptoms laterality was mainly driven by stroke mimics rather than true acute strokes.
The underpinning biology of the laterality preference in DWI-negative patients remains uncertain. This group includes stroke mimics and possibly a small representation of true acute strokes without lesions (TIAs). Reference Tanaka, Coutts and Joundi22 Among stroke mimics, there is little to no evidence for a laterality preference. The higher clinical eloquence and greater metabolic demand of the left hemisphere might suggest a lower resilience and a lower clinical threshold for detecting mimics in the left hemisphere. For instance, hypoglycemia-induced hemiparesis is twice as common with right-sided symptoms. Reference Yoshino, Meguro, Soeda, Itoh, Kawai and Itoh23 In other words, the minimal evidence available supports a preference for right symptoms in stroke mimics rather than left symptoms. Conversely, functional disorders have been consistently associated with a preference for left-sided symptoms. Reference Stern2,Reference Stone, Sharpe and Carson3
There are several potential explanations for this latter phenomenon, which are not mutually exclusive. First, left-sided symptoms represent one of the heralding presentations of acute coronary syndromes due to the distinctive sensory innervation of the heart. Reference Eslick24 This might result in an overrepresentation of left upper arm symptoms in anxious individuals who fear they are experiencing a myocardial infarction. Second, there might be a functional advantage in presenting symptoms on the non-dominant side, which is the left side for the vast majority of individuals. Reference Stone, Sharpe and Carson3 Third, differences in attention or perception of disability in the dominant side might have influenced the outcome. Finally, the right hemisphere is believed to play a more significant role in the mediation of affective or motivationally determined somatic symptoms and has a different spatial representation of the body in comparison to the left hemisphere. Reference Stern2,Reference Stone, Sharpe and Carson3
In our cohort, in the subgroup analyses, the left-sided preference in patients with negative DWI was observed only in those with motor symptoms, but not in those with sensory symptoms. The underlying reasons for this observation remain unclear, yet it is possible that while sensory symptoms are more commonly associated with functional disorders, Reference Hallett, Aybek, Dworetzky, McWhirter, Staab and Stone1 the different body laterality might be more pronounced in motor symptoms. Moreover, the smaller number of patients presenting with sensory symptoms may have limited the ability to detect a statistically significant difference.
Our findings should be interpreted as exploratory, and several limitations must be acknowledged. First, DWI negativity does not fully exclude a vascular etiology, Reference Tanaka, Coutts and Joundi22 and second, we did not evaluate for FNDs. Current diagnostic criteria for FND emphasize the need for positive rule-in signs on neurological exam (e.g., incongruence with known neurological disease, inconsistency and variability, improvement with distraction or automatic movements) and not simply normal imaging. Reference Aybek and Perez14 Moreover, FND can co-occur with structural disease, including stroke, in a minority of cases. Reference Popkirov, Stone and Buchan25 Finally, a variety of alternative diagnoses to functional and vascular disorders are also possible, including neurological (e.g., spinal cord pathologies and neuropathies) or non-neurological (e.g., acute coronary syndrome) conditions. Third, hand dominance or a comprehensive assessment of hemisphere dominance was not collected. Fourth, ethnic differences might influence the clinical presentation of functional disorders. Fifth, multiple subgroup analyses might have increased the risk of type I error in our study. Finally, we defined suspected minor stroke on the persistence of neurological symptoms at the initial medical examination. This pragmatic definition aimed to reduce the proportion of ischemic strokes with negative DWI. However, there was no restriction on the minimum duration from symptom onset, so some TIA patients were likely included.
Notably, our study aims to explain the laterality preference of DWI-negative patients, not to inform diagnostic or therapeutic decision-making in the emergency department.
Conclusion
Unilateral acute left-sided hemiparesis or hemisensory symptoms, compared to right-sided symptoms, were more frequently associated with DWI negativity in a population of suspected minor strokes, with an increased probability of approximately one-third. These findings were mainly driven by the presence of motor symptoms and were consistent across different ages and sexes. Our observations are exploratory, and future studies are needed to replicate them in another cohort and explore the many possible causes driving the relationship between left-sided neurological symptoms and DWI negativity, including FNDs.
Supplementary material
The supplementary material for this article can be found at https://doi.org/10.1017/cjn.2025.10125.
Acknowledgments
None.
Author contributions
UP drafted the manuscript, conceived the study and performed the statistical analysis. NS, RAD, KT, AMP, KV, MMBB, RBF, AMD, MDH and SBC collected the data, revised the manuscript for content, interpreted the results and supervised the study.
Funding statement
The original SpecTRA was supported by Genome British Columbia, Genome Alberta and Genome Canada (grant no. TIA 4125-Penn).
Competing interests
None.
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