Inflammatory Stroke Causes

NeuroWiki

Inflammatory Vasculopathies and Stroke

Inflammatory vasculopathies represent a heterogeneous group of disorders that cause stroke through vessel wall inflammation, thrombosis, or both. While rare compared to atherosclerotic disease, they disproportionately affect younger patients and require specific diagnostic and therapeutic approaches. This article reviews the clinical approach to suspected inflammatory stroke, primary CNS vasculitis, large vessel vasculitides, and inflammatory arteriopathies that mimic classic vasculitis.

🔹 Bottom Line: Inflammatory Stroke

Suspect inflammatory etiology: Multifocal strokes, recurrent events despite optimal prevention, headache/encephalopathy, systemic symptoms, abnormal CSF, vessel wall enhancement, or young age without traditional risk factors
Core workup: MRI with vessel wall imaging, CTA/MRA, lumbar puncture, ESR/CRP, autoimmune panel, infectious studies
PACNS treatment: Glucocorticoids + cyclophosphamide induction → azathioprine/MMF/methotrexate maintenance; rituximab for refractory cases (French COVAC: 80% mRS 0-2 with combined therapy)
GCA: Tocilizumab + steroid taper achieves 56% sustained remission vs 14% placebo (GiACTA); ~50% steroid-sparing effect
Takayasu: TAKT trial showed trend toward benefit with tocilizumab (HR 0.41, p=0.06 ITT); used off-label for refractory disease
Don't miss mimics: RCVS (use RCVS2 score), Susac syndrome (corpus callosum "snowballs"), Sneddon syndrome (livedo + stroke)

Clinical Approach: When to Suspect Inflammatory Stroke

Inflammatory stroke should be considered when clinical and imaging features suggest a non-atherosclerotic mechanism, particularly in patients lacking traditional vascular risk factors. Early recognition is critical, as untreated vasculitis carries high morbidity and mortality.

🔴 Red Flags for Inflammatory Stroke

Multifocal strokes in different vascular territories
Recurrent stroke/TIA despite optimal secondary prevention
Headaches, encephalopathy, or cognitive decline accompanying stroke
Systemic symptoms: fever, weight loss, fatigue, rash, arthritis
Abnormal CSF (elevated protein, pleocytosis)
Vessel wall enhancement on MRI
Young patient (<45 years) without traditional risk factors
Unusual stroke locations (bilateral, posterior fossa, watershed)

Core Diagnostic Bundle

When inflammatory stroke is suspected, a systematic evaluation should include:

Category	Tests	Rationale
Neuroimaging	MRI brain (DWI/FLAIR/SWI/T1 post-contrast) Vessel wall MRI CTA/MRA head and neck	Identify infarct pattern, vessel wall enhancement (inflammation vs atherosclerosis), stenoses/aneurysms
CSF Analysis	Cell count, protein, glucose Oligoclonal bands Infectious studies (VZV PCR, VDRL, cryptococcal antigen)	PACNS: elevated protein (80%), pleocytosis (50-80%); helps exclude infection
Inflammatory Markers	ESR, CRP	Elevated in systemic vasculitis; often normal in PACNS
Autoimmune Panel	ANA, ANCA (PR3/MPO), anti-dsDNA Complement (C3, C4)	Screen for systemic autoimmune disease with CNS involvement
Infectious Workup	HIV, syphilis (RPR/TPPA), VZV IgG/IgM TB (QuantiFERON, chest imaging)	Infectious vasculitis is a critical differential
Additional	Echocardiogram (TTE ± TEE) Hypercoagulable panel if indicated	Exclude embolic source and prothrombotic states

Mimics to Explicitly Exclude

Before diagnosing inflammatory vasculopathy, several important mimics must be ruled out:

Mimic	Key Distinguishing Features
RCVS	Thunderclap headache, triggers (vasoactive drugs, postpartum), normal CSF, vasoconstriction resolves within 12 weeks, RCVS2 score ≥5
Embolic shower	Cardiac source (endocarditis, myxoma), fat embolism (long bone fracture), air embolism, tumor embolism
Intracranial atherosclerosis (ICAD)	Risk factors present, eccentric plaque on vessel wall MRI, no enhancement (or eccentric enhancement)
Arterial dissection	Neck pain, trauma history, intramural hematoma on fat-sat MRI, "flame sign" on angiography
Moyamoya	Bilateral ICA/MCA stenosis with basal collaterals ("puff of smoke"), progressive course
Hypercoagulable states	Venous and arterial thromboses, pregnancy loss, livedo (consider APS if not covered separately)
Drug-induced vasospasm	Sympathomimetics (cocaine, amphetamines), triptans, cannabis, ergotamines

Primary Angiitis of the Central Nervous System (PACNS)

PACNS is a rare vasculitis confined to the CNS, affecting small and medium-sized leptomeningeal and parenchymal vessels. Incidence is approximately 2.4 per million person-years with equal sex distribution and median age at diagnosis of 50 years. The diagnosis requires exclusion of systemic vasculitis and other CNS vasculopathy mimics.

Diagnostic Criteria

🔹 Calabrese-Mallek Criteria (1988)

Criterion 1: Acquired neurologic or psychiatric deficit unexplained by other causes after thorough evaluation
Criterion 2: Classic angiographic features (multifocal segmental stenoses/dilations) OR histopathologic evidence of CNS angiitis
Criterion 3: No evidence of systemic vasculitis or any disorder that could mimic the angiographic or pathologic features

Birnbaum and Hellmann (2009) proposed a modification to improve specificity:

"Definite" PACNS: Histopathologic confirmation of vasculitis on brain/leptomeningeal biopsy
"Probable" PACNS: High-probability angiographic findings + abnormal MRI + CSF profile consistent with PACNS (without tissue confirmation)

Clinical Subtypes

PACNS presents heterogeneously, and recognition of clinical subtypes guides prognosis and treatment intensity:

Subtype	Vessel Size	Features	Diagnosis
Small vessel PACNS	Arterioles, venules	Encephalopathy, cognitive decline, seizures more common; slower progression	Biopsy-positive, angiogram often negative
Medium/large vessel PACNS	Cortical arteries	Focal deficits, stroke-like presentation more common	Angiogram-positive, biopsy may be negative
Mass-lesion variant	Variable	Tumor-like presentation; biopsy essential to exclude malignancy	Biopsy required
Rapidly progressive PACNS	Multiple large vessels	Bilateral, fulminant course; poor response to therapy; high mortality	Usually angiogram-positive
Aβ-related angiitis (ABRA)	Small cortical vessels	Older patients; associated with cerebral amyloid angiopathy; responds to steroids	Biopsy shows amyloid + inflammation

Treatment: Evidence from the French COVAC Cohort

No randomized controlled trials exist for PACNS. Treatment recommendations derive from the French COVAC multicenter cohort (de Boysson et al., Stroke 2018), which evaluated 112 patients with median follow-up of 53 months.

Treatment Strategy	N	mRS 0-2 at Follow-up	Relapse Rate
Glucocorticoids alone	23	43%	High
Glucocorticoids + cyclophosphamide (no maintenance)	42	40%	High
Glucocorticoids + cyclophosphamide + maintenance IS	47	80%	Lower

The combined induction plus maintenance strategy showed significantly better outcomes (p=0.0004). Overall relapse rate was 46%, emphasizing the need for long-term immunosuppression.

🔹 PACNS Treatment Protocol

Induction: High-dose glucocorticoids (methylprednisolone 1g IV × 3-5 days → prednisone 1 mg/kg/day) + cyclophosphamide (IV pulses 0.5-0.75 g/m² monthly × 6 or oral 2 mg/kg/day × 3-6 months)
Maintenance: Azathioprine (2 mg/kg/day), mycophenolate mofetil (2-3 g/day), or methotrexate (15-25 mg/week) for ≥2 years
Refractory disease: Rituximab 375 mg/m² weekly × 4 or 1000 mg × 2 doses; monitor CD19/CD20 for re-dosing (typically every 6 months)
Steroid taper: Begin after 4-6 weeks of induction; taper over 6-12 months to lowest effective dose

Large Vessel Vasculitis

Giant Cell Arteritis (GCA)

GCA is the most common primary systemic vasculitis in adults over 50, with an incidence of 15-25 per 100,000 in populations of Northern European ancestry. While cranial involvement (temporal arteritis) is classic, large vessel GCA affecting the aorta and its branches is increasingly recognized and carries stroke risk through vertebral, carotid, or aortic arch involvement.

2022 ACR/EULAR Classification Criteria

These criteria apply to patients with confirmed medium- or large-vessel vasculitis. Age ≥50 years at diagnosis is an absolute requirement. A cumulative score ≥6 points classifies GCA.

Criterion	Points
Positive temporal artery biopsy OR halo sign on temporal artery ultrasound	+5
ESR ≥50 mm/hr OR CRP ≥10 mg/L	+3
Sudden visual loss	+3
Morning stiffness in shoulders or neck	+2
Jaw or tongue claudication	+2
New temporal headache	+2
Scalp tenderness	+2
Temporal artery abnormality on examination (tenderness, decreased pulse)	+2
Bilateral axillary artery involvement on imaging	+2
FDG-PET activity throughout the aorta	+2

Validation showed sensitivity of 87% and specificity of 95% (AUC 0.91). These criteria perform better than the 1990 ACR criteria, particularly for large-vessel GCA phenotypes.

GiACTA Trial: Tocilizumab for GCA

The GiACTA trial (Stone et al., NEJM 2017) established tocilizumab as a steroid-sparing treatment for GCA. This phase 3 RCT randomized 251 patients with new-onset or relapsing GCA to four arms:

Arm	Intervention	Sustained Remission at 52 Weeks
Tocilizumab weekly	TCZ 162 mg SC weekly + 26-week prednisone taper	56%
Tocilizumab Q2W	TCZ 162 mg SC every 2 weeks + 26-week taper	53%
Placebo + 26-week taper	Placebo + 26-week prednisone taper	14%
Placebo + 52-week taper	Placebo + 52-week prednisone taper	18%

Both tocilizumab arms were superior to placebo (p<0.001). Median cumulative prednisone dose was 1,862 mg in tocilizumab arms versus 3,296-3,818 mg in placebo arms—approximately 50% steroid-sparing effect. Long-term extension data (GiACTA Part 2, Lancet Rheumatology 2021) showed ~48% of patients maintained drug-free remission after stopping tocilizumab, with weekly dosing superior to Q2W in relapsing disease.

🔹 Clinical Relevance: GCA and Stroke Prevention

Stroke mechanisms in GCA: Vertebral/carotid involvement (particularly extracranial), aortic arch disease, rarely intracranial involvement
Vision loss is the emergency: Anterior ischemic optic neuropathy (AION) requires immediate high-dose steroids; tocilizumab does not replace steroids acutely
Treatment algorithm: New-onset or relapsing GCA → tocilizumab 162 mg SC weekly (or Q2W) + accelerated prednisone taper (26 weeks); weekly preferred for relapsing disease
Duration: 1 year of tocilizumab may be sufficient; many maintain remission after discontinuation
Monitoring caveat: Tocilizumab suppresses CRP/ESR; clinical monitoring essential during treatment

Takayasu Arteritis

Takayasu arteritis (TAK) is a large vessel vasculitis affecting the aorta and its major branches, predominantly in women under 40 years. Stroke mechanisms include subclavian steal, carotid stenosis, and cardiac embolism from aortic regurgitation. Incidence is 2-3 per million in Western populations but higher in Japan and Asia.

TAKT Trial: Tocilizumab for Takayasu Arteritis

The TAKT trial (Nakaoka et al., Ann Rheum Dis 2018) was the only phase 3 RCT of tocilizumab in TAK. This Japanese study randomized 36 patients with refractory, relapsing TAK to tocilizumab 162 mg SC weekly versus placebo, with glucocorticoid tapering.

Outcome	Tocilizumab	Placebo	HR (95% CI)	P-value
Relapse-free at 24 weeks (ITT)	51%	23%	0.41 (0.15-1.10)	0.06
Relapse-free at 24 weeks (per-protocol)	52%	17%	0.34 (0.11-1.00)	0.03

The primary endpoint was not met in the intention-to-treat analysis, though trends favored tocilizumab. The study was likely underpowered (N=36). Long-term extension (TAKT 96-week, Rheumatology 2020) showed 46% of patients reduced glucocorticoid dose to <0.1 mg/kg/day, and 86% of arteries remained stable or improved on imaging.

🔹 Clinical Relevance: Takayasu Arteritis Management

First-line therapy: High-dose glucocorticoids (prednisone 1 mg/kg/day); 50% achieve remission but relapse rates are high
Refractory disease: Consider tocilizumab (off-label) or TNF inhibitors (infliximab); limited RCT evidence
TAKT takeaway: Suggestive benefit with tocilizumab, significant steroid-sparing in extension; not FDA-approved for TAK but used off-label
Surgical/endovascular intervention: Reserved for critical stenoses; avoid during active inflammation
Monitoring: Clinical assessment, inflammatory markers, serial CTA/MRA or PET

Medium and Small Vessel Vasculitis

Systemic small and medium vessel vasculitides can involve the CNS, though isolated CNS involvement is rare. Key entities include:

Vasculitis	Vessel Size	CNS Manifestations	Key Features
GPA (Wegener's)	Small	Pachymeningitis, pituitary involvement, orbital pseudotumor, rare stroke	PR3-ANCA positive; upper/lower respiratory, renal involvement
MPA	Small	Peripheral neuropathy > CNS; mononeuritis multiplex	MPO-ANCA positive; pulmonary-renal syndrome
EGPA (Churg-Strauss)	Small	Peripheral neuropathy (70%); CNS rare	Asthma, eosinophilia, MPO-ANCA (40%)
Polyarteritis nodosa	Medium	Stroke, hemorrhage, aneurysms	ANCA-negative; HBV association; renal/mesenteric involvement
Behçet disease	Variable	Venous sinus thrombosis (most common), parenchymal neuro-Behçet, arterial aneurysms	Oral/genital ulcers, uveitis, pathergy; HLA-B51

Treatment typically follows protocols for the underlying systemic vasculitis. For ANCA-associated vasculitis, the RAVE trial demonstrated rituximab non-inferiority to cyclophosphamide for induction, with potential superiority in relapsing disease.

Inflammatory Arteriopathies That Aren't Classic Vasculitis

Several conditions cause stroke through inflammatory or microangiopathic mechanisms but do not fit the classic vasculitis paradigm. Recognition is essential as treatment differs significantly.

Susac Syndrome

Susac syndrome is an autoimmune endotheliopathy affecting precapillary arterioles of the brain, retina, and cochlea. It predominantly affects young women (mean age 31, F:M ratio 3.5:1) and is often misdiagnosed as multiple sclerosis or ADEM.

Clinical Triad	Features	Key Diagnostic Finding
Encephalopathy	Cognitive impairment, confusion, behavioral changes, headache, psychiatric symptoms	MRI: "Snowball" lesions in central corpus callosum (pathognomonic)
Branch retinal artery occlusions (BRAO)	Scotomata, visual disturbances; often peripheral and asymptomatic	Fluorescein angiography: BRAO, Gass plaques (yellow arterial wall plaques)
Sensorineural hearing loss	Low and mid-frequency loss; tinnitus; often sudden onset	Audiometry: Low/mid-frequency SNHL

Critical point: The complete triad is present at onset in only 13% of cases. Components may appear sequentially over months to years, leading to diagnostic delay (mean 3 months when criteria met, up to 10 months with partial presentation).

🔹 Susac Syndrome: Diagnosis and Treatment

Diagnostic workup: MRI brain (central callosal "snowball" lesions), fluorescein angiography (BRAO, arteriolar wall hyperfluorescence, Gass plaques), audiometry
Differentiating from MS: Susac affects central corpus callosum fibers; MS typically affects callosal undersurface. OCT shows retinal infarcts in Susac vs optic nerve thinning in MS
Treatment: Aggressive immunosuppression early prevents permanent deficits
- Acute: IV methylprednisolone + IVIG ± cyclophosphamide or rituximab
- Maintenance: MMF or azathioprine; very slow steroid taper over 2+ years
Prognosis: Usually self-limiting (1-4 years) but may leave residual cognitive, visual, and hearing deficits. Cochlear implants for severe hearing loss

Sneddon Syndrome

Sneddon syndrome is a non-inflammatory thrombotic vasculopathy characterized by livedo racemosa and recurrent ischemic strokes or TIAs. It predominantly affects women aged 20-42 years, with estimated incidence of 4 per million annually.

Feature	Description
Livedo racemosa	Persistent, irregular, broken circular violaceous pattern; trunk and buttocks predominantly; does NOT resolve with warming (unlike livedo reticularis)
Cerebrovascular events	Recurrent TIAs and strokes (usually MCA/PCA territory); progressive cognitive decline; may lead to vascular dementia
Temporal relationship	Livedo precedes neurologic symptoms by ~10 years
Antiphospholipid antibodies	Present in ~60% (aPL-positive Sneddon); absence defines aPL-negative subtype

Diagnosis: Deep skin biopsy from the center (not ring) of livedo lesions showing non-inflammatory thrombotic occlusion of small/medium dermal arteries. Sensitivity improves with multiple biopsies: 27% (1 biopsy), 53% (2 biopsies), 80% (3 biopsies). Brain MRI shows multifocal white matter infarcts.

🔹 Sneddon Syndrome: Management

aPL-positive: Anticoagulation with warfarin (target INR 3-4 often recommended); similar to APS management
aPL-negative: Less clear; antiplatelet therapy may be sufficient; some recommend warfarin
Avoid: Estrogen-containing contraceptives, smoking
Immunosuppression: Generally ineffective (non-inflammatory); anecdotal responses reported in aPL-positive cases
Prognosis: Chronic, progressive; cognitive decline common even with treatment

Radiation-Induced Vasculopathy

Cranial and cervical radiation can cause delayed cerebrovascular complications through accelerated atherosclerosis, fibrous intimal thickening, and moyamoya-like vasculopathy. Risk increases with radiation dose >50 Gy and young age at treatment.

Latency: Typically 5-20 years post-radiation; can be decades
Patterns: Carotid stenosis (most common), intracranial stenosis, moyamoya-like collateralization
Management: Standard stroke prevention; revascularization (bypass, stenting) for symptomatic stenosis; no role for immunosuppression

PACNS vs Systemic Vasculitis vs RCVS: Diagnostic Comparison

Feature	PACNS	Systemic Vasculitis (CNS)	RCVS
Demographics	Any age; M=F	Varies by disease	Women 20-50
Onset	Subacute/chronic (weeks-months)	Variable	Acute; thunderclap headache
Headache	Gradual, progressive	Variable	Thunderclap (peak <1 min)
Systemic symptoms	Absent	Present (fever, rash, arthritis, renal)	Absent
Triggers	None	None	Vasoactive drugs, postpartum, exertion, Valsalva
CSF	Abnormal (80%): elevated protein, pleocytosis	Variable	Usually normal (or minimal protein elevation)
ESR/CRP	Normal or mildly elevated	Elevated	Normal
Angiography	Multifocal stenoses/dilations; persists	Similar pattern	"String of beads"; resolves in ≤12 weeks
Vessel wall MRI	Concentric enhancement	Enhancement	Absent or faint, non-concentric enhancement
RCVS2 Score	<5	Variable	≥5 (high probability)
Brain biopsy	Diagnostic (granulomatous, lymphocytic, necrotizing)	May show vasculitis	Normal
Response to steroids	Yes	Yes	No benefit (may worsen)
Prognosis	Chronic; requires long-term IS	Depends on underlying disease	Self-limiting; resolves in weeks

Treatment Principles and Safety Monitoring

Glucocorticoid Prophylaxis

Long-term steroid use requires vigilant prophylaxis against complications:

PJP prophylaxis: TMP-SMX (single-strength daily or double-strength 3×/week) if prednisone ≥20 mg for >4 weeks AND additional immunosuppression
Bone protection: Calcium (1000-1200 mg/day), vitamin D (800-2000 IU/day); bisphosphonate if high fracture risk (T-score <-1.5 or prior fragility fracture)
GI prophylaxis: PPI if concurrent NSAID or anticoagulation; H2 blocker otherwise acceptable
Glucose monitoring: Check fasting glucose at baseline and periodically; steroid-induced diabetes common
Blood pressure: Monitor and treat hypertension

Cyclophosphamide Monitoring

CBC: Every 1-2 weeks during induction; hold if WBC <3,500 or ANC <1,500
Bladder protection: Aggressive hydration; mesna with IV cyclophosphamide; avoid overnight bladder retention
Fertility: Counsel on gonadal toxicity; consider sperm banking or oocyte cryopreservation before treatment
Cumulative dose: Lifetime limit ~25g to minimize malignancy risk (bladder cancer, lymphoma)
Infection surveillance: Monitor for opportunistic infections; low threshold for empiric treatment

Relapse Monitoring

Clinical assessment: Regular neurologic examination; ask about new headaches, cognitive changes, focal symptoms
Imaging: Serial MRI every 3-6 months during active treatment, then annually; vessel wall imaging if available
CSF: Consider repeat LP if clinical concern for relapse
Lab monitoring: ESR/CRP helpful in systemic vasculitis; less reliable in PACNS or when on tocilizumab (suppresses acute phase reactants)

Antithrombotic Therapy: Entity-Specific Approach

🔴 Antithrombotic Cautions in Inflammatory Vasculopathy

Active CNS vasculitis: Anticoagulation generally NOT indicated unless specific indication (AF, DVT/PE); may increase hemorrhagic risk
Post-stroke: Standard secondary prevention (antiplatelet) once acute inflammation controlled and hemorrhage excluded
Sneddon syndrome: Anticoagulation with warfarin (aPL-positive) or antiplatelet (aPL-negative)
Behçet with CVT: Anticoagulation is standard; duration debated (often long-term)
GCA: Low-dose aspirin often recommended for cardiovascular protection; no proven benefit for stroke prevention specifically
Avoid blanket statements: Individualize based on etiology, stroke mechanism, and bleeding risk

Anti-Inflammatory Strategies: Current Evidence

The concept of targeting residual inflammatory risk for stroke prevention has generated interest, particularly with colchicine. However, stroke-specific trials have been disappointing:

Trial	Year	Population	Intervention	Result
CHANCE-3	2023	Minor stroke/TIA with CRP ≥2 mg/L (N=8,369)	Colchicine 0.5 mg daily × 90 days vs placebo	Neutral: Stroke 6.3% vs 6.5% (p=NS)
CONVINCE	2024	Non-cardioembolic stroke/TIA (N=3,154)	Colchicine 0.5 mg daily vs usual care	Neutral: MACE 9.8% vs 11.7% (HR 0.84, p=0.12)
CLEAR Colchicine	2024	Post-MI (N=7,062)	Colchicine 0.5 mg daily vs placebo	Neutral: Primary composite 9.1% vs 9.3% (p=0.93)

A meta-analysis pooling CONVINCE with coronary trials (COLCOT, LoDoCo2) showed a 27% reduction in ischemic stroke (RR 0.73, p<0.004), but stroke-dedicated trials have not confirmed benefit. Colchicine is not currently recommended for routine stroke secondary prevention.

Trial Comparison Table

Trial	Year	Population	N	Intervention	Primary Outcome	Key Result
GiACTA	2017	GCA (new/relapsing)	251	Tocilizumab 162 mg SC weekly or Q2W + 26-wk taper vs placebo	Sustained remission at 52 wks	56% vs 14% (p<0.001); 50% steroid-sparing
GiACTA Long-term	2021	GCA (extension)	215	Open-label tocilizumab	Drug-free remission	~48% maintained remission after stopping TCZ
TAKT	2018	Takayasu (refractory)	36	Tocilizumab 162 mg SC weekly vs placebo	Time to relapse	HR 0.41 (p=0.06 ITT); 0.34 (p=0.03 PP)
TAKT Longterm	2020	Takayasu (extension)	36	Open-label tocilizumab × 96 wks	Steroid-sparing, imaging	46% reduced to <0.1 mg/kg/day; 86% stable/improved imaging
French COVAC	2018	PACNS	112	GC alone vs GC+CYC vs GC+CYC+maintenance	mRS 0-2	43% vs 40% vs 80% (p=0.0004)
CHANCE-3	2023	Minor stroke/TIA, CRP ≥2	8,369	Colchicine 0.5 mg daily × 90 days	Stroke at 90 days	6.3% vs 6.5% (NS)
CONVINCE	2024	Non-CE stroke/TIA	3,154	Colchicine 0.5 mg daily	MACE	9.8% vs 11.7% (HR 0.84, p=0.12)

References

Calabrese LH, Mallek JA. Primary angiitis of the central nervous system: Report of 8 new cases, review of the literature, and proposal for diagnostic criteria. Medicine (Baltimore). 1988;67:20-39.
Birnbaum J, Hellmann DB. Primary angiitis of the central nervous system. Arch Neurol. 2009;66:704-709.
de Boysson H, et al. Primary angiitis of the CNS: A prospective study in 112 patients. Neurology. 2014;83:1284-1291.
de Boysson H, et al. Management and outcomes of primary angiitis of the central nervous system: A French multicentric prospective cohort (COVAC). Stroke. 2018;49:1946-1953.
Stone JH, et al. Trial of tocilizumab in giant-cell arteritis. N Engl J Med. 2017;377:317-328. (GiACTA)
Stone JH, et al. Long-term effect of tocilizumab in patients with giant cell arteritis: 3-year data from GiACTA. Lancet Rheumatol. 2021;3:e328-e336.
Ponte C, et al. 2022 American College of Rheumatology/EULAR classification criteria for giant cell arteritis. Arthritis Rheumatol. 2022;74:1881-1889.
Nakaoka Y, et al. Efficacy and safety of tocilizumab in patients with refractory Takayasu arteritis: Results from a randomised, double-blind, placebo-controlled, phase 3 trial in Japan (the TAKT study). Ann Rheum Dis. 2018;77:348-354.
Nakaoka Y, et al. Long-term efficacy and safety of tocilizumab in refractory Takayasu arteritis: Final results of the randomized controlled phase 3 TAKT study. Rheumatology. 2020;59:2427-2434.
Kleffner I, et al. Diagnostic criteria for Susac syndrome. J Neurol Neurosurg Psychiatry. 2016;87:1287-1295.
Dörr J, et al. Characteristics of Susac syndrome: A review of all reported cases. Nat Rev Neurol. 2013;9:307-316.
Wu S, et al. Sneddon's syndrome: A comprehensive review of the literature. Orphanet J Rare Dis. 2014;9:215.
Pascarella R, et al. European Stroke Organisation (ESO) guidelines on Primary Angiitis of the Central Nervous System (PACNS). Eur Stroke J. 2023;8:680-706.
Wang Y, et al. Effect of colchicine on stroke in patients with minor to moderate ischemic stroke or TIA: The CHANCE-3 randomized clinical trial. World Stroke Congress 2023.
Kelly P, et al. Long-term colchicine for the prevention of vascular recurrent events in non-cardioembolic stroke (CONVINCE): A randomised controlled trial. Lancet. 2024;404:125-133.