Laboratory Tests

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Laboratory Testing in Stroke: From Routine Workup to Rare Diagnoses

Laboratory testing in stroke serves multiple purposes: identifying modifiable risk factors, determining stroke etiology, guiding secondary prevention, monitoring therapeutic efficacy, and uncovering rare mimics or genetic conditions. While most patients require only routine metabolic workup, specialized testing is essential when clinical features suggest unusual etiologies—particularly in young patients, cryptogenic strokes, or atypical presentations.

🔹 Bottom Line: Laboratory Testing in Stroke

Routine labs: Lipid panel (target LDL <70 mg/dL per TST), HbA1c, BMP, CBC for all ischemic stroke patients.
Lp(a): Consider in cryptogenic stroke or premature atherosclerosis; elevated levels indicate residual risk despite statin therapy.
Hypercoagulable panel: Reserve for young stroke (<50), cryptogenic with venous features, recurrent strokes, or clinical APS suspicion.
D-dimer: Markedly elevated levels with multiterritory infarcts suggest Trousseau syndrome—pursue malignancy workup.
Therapeutic monitoring: Platelet function assays, anti-Xa levels, and INR can assess antithrombotic efficacy and adherence.
Rare diagnoses: Consider Fabry (young, posterior circulation), MELAS (cortical strokes, seizures, lactate), APS (miscarriages, clots), sickle cell (African descent, moyamoya pattern).

Part I: Routine Laboratory Testing

Lipid Panel

Dyslipidemia is a major modifiable risk factor for atherosclerotic stroke. The SPARCL trial demonstrated that high-dose atorvastatin (80 mg) reduced recurrent stroke by 16% in patients with recent stroke/TIA. The TST (Treat Stroke to Target) trial showed that targeting LDL <70 mg/dL reduced major cardiovascular events compared to a target of 90–110 mg/dL in patients with atherosclerotic stroke.

Lipid Parameter	Optimal Target	Clinical Relevance
LDL Cholesterol	<70 mg/dL (atherosclerotic disease) <55 mg/dL (very high risk, ESC), otherwise <100 if no atherosclerotic disease	Primary target; reduction lowers ischemic stroke risk; SPARCL, TST evidence
Total Cholesterol	<200 mg/dL	General cardiovascular risk marker
HDL Cholesterol	>40 mg/dL (men) >50 mg/dL (women)	Low HDL associated with increased stroke risk; no proven benefit from pharmacologic elevation
Triglycerides	<150 mg/dL	Elevated TG contributes to residual risk; icosapent ethyl reduces CV events in hypertriglyceridemia (REDUCE-IT)
Non-HDL Cholesterol	<100 mg/dL	Captures all atherogenic lipoproteins; useful when TG elevated

Lipoprotein(a) — Lp(a)

Lp(a) is a genetically determined, LDL-like particle that confers independent cardiovascular risk not modified by statins. Elevated Lp(a) (>50 mg/dL or >125 nmol/L) is associated with increased stroke and MI risk. Consider testing in:

Cryptogenic stroke, especially with premature atherosclerosis
Family history of early cardiovascular disease
Recurrent events despite optimal LDL control
Patients with borderline indications for aggressive lipid therapy

Limitation: No approved Lp(a)-lowering therapies yet, though antisense oligonucleotides (pelacarsen) are in phase 3 trials. Current management includes aggressive LDL reduction, PCSK9 inhibitors (modest Lp(a) lowering), and consideration of aspirin for primary prevention in high-risk individuals.

Glycemic Assessment

HbA1c reflects average glucose over 2–3 months and is diagnostic for diabetes (≥6.5%) or prediabetes (5.7–6.4%). Diabetes doubles stroke risk and worsens outcomes. Target HbA1c <7% for most stroke patients; individualize for elderly or those with hypoglycemia risk.

Admission glucose: Hyperglycemia at presentation (even without diabetes) is associated with larger infarct volumes and worse outcomes. Target glucose 140–180 mg/dL in the acute setting; avoid hypoglycemia.

Basic Metabolic Panel & CBC

Routine testing provides essential baseline data:

Creatinine/eGFR: Guides contrast use, DOAC dosing, and identifies CKD as a stroke risk factor
Electrolytes: Hyponatremia may occur with cerebral salt wasting; hyperglycemia affects osmolality
Hemoglobin/Hematocrit: Anemia worsens outcomes; polycythemia increases viscosity
Platelet count: Thrombocytopenia affects antiplatelet choice; thrombocytosis may be reactive or myeloproliferative

Part II: Inflammatory & Thrombotic Markers

C-Reactive Protein (hs-CRP)

High-sensitivity CRP is a marker of systemic inflammation and atherosclerotic risk. Elevated hs-CRP (>2 mg/L) identifies patients with "residual inflammatory risk" who may benefit from intensified therapy. The JUPITER trial showed that rosuvastatin reduced cardiovascular events in patients with elevated CRP even with normal LDL—though routine CRP-guided therapy remains debated in stroke.

Clinical utility: May help risk-stratify patients with borderline indications for statin therapy or identify those who might benefit from anti-inflammatory approaches (colchicine trials ongoing in stroke).

Erythrocyte Sedimentation Rate (ESR)

ESR is a nonspecific inflammatory marker with particular importance in suspected giant cell arteritis (GCA):

When to order: Older patient (>50 years) with new headache, jaw claudication, scalp tenderness, visual symptoms, or unexplained constitutional symptoms
Concerning threshold: ESR >50 mm/hr raises suspicion; >100 mm/hr highly concerning for GCA
Action: If GCA suspected, start empiric steroids immediately and obtain temporal artery biopsy; do not delay treatment for biopsy

Also consider ESR/CRP in suspected CNS vasculitis, endocarditis, or systemic inflammatory conditions.

D-Dimer

D-dimer is not part of routine stroke workup but becomes important when cancer-associated thrombosis (Trousseau syndrome) is suspected:

🔴 Red Flags for Trousseau Syndrome

Multiterritory infarcts ("Trousseau 3-vessel sign")—simultaneous strokes in different vascular territories
Unexplained weight loss, anorexia, or constitutional symptoms
Migratory superficial thrombophlebitis
Concurrent DVT/PE or unusual thrombosis sites
Markedly elevated D-dimer (>2–3× upper limit of normal)

Action: If Trousseau suspected, pursue CT chest/abdomen/pelvis, age-appropriate cancer screening, and consider anticoagulation (LMWH often preferred over DOACs in active malignancy).

Part III: Antithrombotic Therapeutic Monitoring

Laboratory testing can assess whether antithrombotic therapy is effective and whether patients are adherent. This is particularly useful in patients with recurrent events despite therapy or when drug interactions/metabolism concerns exist.

Medication	Assay	Interpretation	Clinical Use
Aspirin	Platelet function assay (VerifyNow Aspirin, PFA-100)	ARU <550 suggests adequate inhibition	Suspected non-adherence, aspirin "resistance," recurrent events
Clopidogrel	P2Y12 platelet function assay (VerifyNow P2Y12)	PRU <208 suggests adequate inhibition; >230 = high on-treatment reactivity	CYP2C19 poor metabolizers, recurrent events, suspected non-adherence
Clopidogrel	CYP2C19 genotyping	2/2, 2/3, 3/3 = poor metabolizers	Consider alternative (ticagrelor, prasugrel) if loss-of-function alleles
Warfarin	INR (PT/INR)	Target INR 2.0–3.0 (most indications); 2.5–3.5 (mechanical valves)	Routine monitoring required; narrow therapeutic window
Apixaban	Anti-Xa assay (apixaban-calibrated)	Drug-specific calibration required; trough >50 ng/mL suggests therapeutic level	Suspected accumulation (renal impairment), bleeding, recurrent events, adherence
Rivaroxaban	Anti-Xa assay (rivaroxaban-calibrated)	Peak levels vary by dose; trough detectable confirms recent intake	Similar to apixaban; timing relative to dose matters
Dabigatran	Dilute thrombin time (dTT), Ecarin clotting time (ECT)	Prolonged dTT/ECT confirms drug presence; quantitative assays available	Pre-procedure assessment, bleeding, suspected accumulation
Heparin (UFH)	Anti-Xa assay or aPTT	Anti-Xa 0.3–0.7 IU/mL (therapeutic); aPTT 1.5–2.5× control	Routine monitoring for IV heparin infusion
LMWH (enoxaparin)	Anti-Xa assay	Peak (4h post-dose): 0.5–1.0 IU/mL (BID) or 1.0–2.0 IU/mL (daily)	Obesity, renal impairment, pregnancy, extremes of weight

Note: Routine monitoring of DOACs is not recommended, but targeted testing is valuable in specific scenarios. PT/INR and aPTT are affected by DOACs and should not be used to assess their therapeutic effect.

Part IV: Hypercoagulable Panel

🔹 When to Order a Hypercoagulable Panel

Ischemic stroke in young patient (<50 years) without clear etiology
Cryptogenic stroke with venous features: concurrent DVT/PE, history of VTE, pregnancy losses
Cerebral venous thrombosis or unusual clot locations (splanchnic, upper extremity)
Recurrent arterial events despite appropriate antithrombotic therapy
Clinical features suggesting APS: livedo reticularis, recurrent miscarriages, prolonged aPTT, valve vegetations
Family history of unprovoked VTE or arterial thrombosis at young age
Do NOT routinely order in typical elderly stroke with clear atherosclerotic or cardioembolic etiology

Hypercoagulable Panel Components

Test	Condition Detected	Notes
Antiphospholipid Syndrome (APS) — Highest Yield for Arterial Stroke
Lupus anticoagulant (LA)	APS	Most specific for thrombosis; affected by anticoagulants—test before starting or after washout
Anticardiolipin antibodies (IgG, IgM)	APS	Medium-high titers clinically significant; can test on anticoagulation
Anti-β2-glycoprotein I (IgG, IgM)	APS	Most specific antibody; triple-positive (all 3) = highest risk
Inherited Thrombophilias — Primarily Venous Risk
Factor V Leiden mutation	Activated protein C resistance	Most common inherited thrombophilia; mainly venous risk; arterial role debated
Prothrombin G20210A mutation	Elevated prothrombin levels	Second most common; primarily venous thrombosis
Protein C activity	Protein C deficiency	Decreased in acute thrombosis, liver disease, warfarin use—recheck when stable
Protein S activity (free)	Protein S deficiency	Affected by pregnancy, OCP, acute illness, warfarin—timing matters
Antithrombin III activity	Antithrombin deficiency	Decreased by heparin, acute thrombosis, liver disease; heparin resistance if deficient
Other Tests
Homocysteine	Hyperhomocysteinemia	Elevated levels associated with stroke; B-vitamin supplementation reduces levels but not events (VITATOPS)
Factor VIII activity	Elevated factor VIII	Persistently elevated levels (>150%) associated with VTE recurrence

Timing considerations: Acute thrombosis, anticoagulation, and illness affect many results. Protein C, protein S, and antithrombin are best tested when clinically stable and off anticoagulation (or on stable warfarin for protein C/S). Lupus anticoagulant requires testing off heparin/DOACs. Anticardiolipin and anti-β2GP1 can be tested on anticoagulation. Confirm positive results at least 12 weeks apart for APS diagnosis.

Part V: Specialized Testing for Rare Etiologies

When clinical features suggest a specific rare diagnosis, targeted testing can be diagnostic. The table below summarizes key clinical scenarios and corresponding investigations.

Clinical Scenario	Consider	Key Testing
Young adult, recurrent posterior circulation strokes, basilar dolichoectasia, renal insufficiency, cardiomyopathy, acroparesthesias, angiokeratomas	Fabry disease	Alpha-galactosidase A enzyme activity (males); genetic testing (GLA gene); Lyso-Gb3 (globotriaosylsphingosine) biomarker
Young African American or Caribbean descent, moyamoya pattern on imaging, childhood stroke history, hemolytic anemia	Sickle cell disease	Hemoglobin electrophoresis; CBC with reticulocyte count; peripheral smear
Young adult, strokes not respecting vascular territories, cortical predilection, history of migraine, seizures, sensorineural hearing loss, short stature, elevated lactate	MELAS (mitochondrial encephalomyopathy, lactic acidosis, stroke-like episodes)	Serum and CSF lactate; genetic testing: mtDNA analysis (m.3243A>G most common) + whole exome sequencing; muscle biopsy (ragged red fibers)
Young adult, stroke-like episodes, basal ganglia calcifications on CT, seizures, progressive external ophthalmoplegia	POLG-related disorders (MELAS-like)	POLG gene sequencing; mtDNA analysis; serum lactate; consider muscle biopsy
Multiterritory infarcts, markedly elevated D-dimer, unexplained weight loss, migratory thrombophlebitis	Trousseau syndrome (occult malignancy)	D-dimer; CT chest/abdomen/pelvis; age-appropriate cancer screening (colonoscopy, mammogram, PSA); consider PET-CT if high suspicion
Young patient, ESUS, prior miscarriages or stillbirths, history of DVT/PE, livedo reticularis, prolonged aPTT, cardiac valve vegetations	Antiphospholipid syndrome	Lupus anticoagulant, anticardiolipin Ab, anti-β2GP1 Ab; confirm positivity at 12 weeks; TRAPS: warfarin superior to rivaroxaban in triple-positive APS
Older patient (>50), new headache, jaw claudication, visual changes, scalp tenderness, elevated inflammatory markers	Giant cell arteritis	ESR, CRP; temporal artery biopsy; temporal artery ultrasound ("halo sign"); do NOT delay steroids for biopsy
Young stroke, multifocal stenoses, systemic inflammation, encephalopathy, headache, CSF pleocytosis	CNS vasculitis (primary or secondary)	CSF analysis (cells, protein, OCBs); ESR, CRP, ANA, ANCA; vessel wall MRI; DSA (beading); brain/leptomeningeal biopsy if needed
Young patient, stroke with skin lesions, livedo racemosa, cognitive decline, no inflammation	Sneddon syndrome	Skin biopsy (endothelial proliferation, thrombosis of medium vessels); APS workup; vessel wall MRI
Stroke with cocaine or amphetamine use, severe hypertension, vasoconstriction on imaging	Drug-induced vasospasm/vasculitis	Urine drug screen; vessel imaging (CTA/MRA may show beading or vasoconstriction)

Genetic Testing for Mitochondrial Disease

When MELAS or other mitochondrial disorders are suspected, comprehensive genetic testing includes:

mtDNA point mutation analysis: Targets common mutations (m.3243A>G accounts for ~80% of MELAS)
mtDNA deletion/duplication analysis: For suspected Kearns-Sayre or other deletion syndromes
Whole exome sequencing (WES): Identifies nuclear gene mutations affecting mitochondrial function (POLG, TWNK, etc.)
mtDNA whole genome sequencing: Comprehensive mitochondrial genome analysis

Testing can be performed on blood, though heteroplasmy levels vary by tissue. If blood testing is negative but clinical suspicion remains high, consider testing urine sediment or muscle biopsy tissue where mutation load may be higher.

CSF Analysis

Lumbar puncture is indicated when CNS vasculitis, infection, or inflammatory conditions are suspected:

Cell count: Pleocytosis (lymphocyte-predominant) in vasculitis, infection
Protein: Elevated in inflammation, infection, malignancy
Glucose: Low in bacterial/fungal infection, carcinomatous meningitis
Oligoclonal bands: Present in MS, neurosarcoidosis, some vasculitides
Lactate: Elevated in MELAS (>2.2 mmol/L), bacterial meningitis
Cytology/flow cytometry: If lymphoma or carcinomatous meningitis suspected
Infectious studies: HSV PCR, VZV PCR, fungal cultures/antigens as indicated

Part VI: Summary — What to Order When

Clinical Context	Laboratory Tests
All ischemic stroke patients	Lipid panel (fasting preferred), HbA1c, BMP, CBC, PT/INR
Atherosclerotic stroke (LAA)	Above + consider Lp(a), hs-CRP if risk stratification needed
Cryptogenic stroke, age <50	Above + hypercoagulable panel (APS antibodies priority), consider Lp(a), drug screen
Suspected APS	Lupus anticoagulant, anticardiolipin IgG/IgM, anti-β2GP1 IgG/IgM; confirm at 12 weeks
Suspected Trousseau/malignancy	D-dimer, CBC, CMP, LDH, age-appropriate cancer screening, CT CAP, consider PET
Suspected GCA	ESR, CRP, CBC (thrombocytosis, anemia); proceed to biopsy, do not delay steroids
Suspected CNS vasculitis	ESR, CRP, ANA, ANCA, complement; CSF analysis; consider vessel wall MRI, DSA
Suspected MELAS	Serum lactate, CSF lactate; mtDNA analysis + WES; consider muscle biopsy
Suspected Fabry disease	Alpha-galactosidase A activity; GLA gene sequencing; Lyso-Gb3 biomarker
Recurrent stroke on antithrombotic	Verify adherence; platelet function assay (if on antiplatelet); anti-Xa or INR (if on anticoagulant); CYP2C19 genotype (if on clopidogrel)

References

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Ridker PM, et al. Rosuvastatin to prevent vascular events in men and women with elevated C-reactive protein (JUPITER). N Engl J Med. 2008;359:2195-2207.
Pengo V, et al. Rivaroxaban vs warfarin in high-risk patients with antiphospholipid syndrome (TRAPS). Blood. 2018;132:1365-1371.
Grant EG, et al. Society of Radiologists in Ultrasound Consensus Conference on carotid stenosis. Radiology. 2003;229:340-346.
Miyatake S, et al. Clinical determinants of stroke-like episodes in MELAS. J Neurol. 2011;258:2073-2079.
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