Neurovascular and Neurocognitive Consequences of Iron Deficiency Anemia
Overview
- Phase
- Phase 4
- Intervention
- Ferric derisomaltose
- Conditions
- IDA - Iron Deficiency Anemia
- Sponsor
- Children's Hospital Los Angeles
- Enrollment
- 120
- Locations
- 4
- Primary Endpoint
- Impact of iron deficiency anemia on regional cerebrovascular oxygen delivery (ml O2/100g/min).
- Status
- Recruiting
- Last Updated
- last year
Overview
Brief Summary
This is a trial with an observational and an interventional arm, in patients with moderate to severe anemia and control subjects. The main purposes of this study is to phenotype the scope of neurocognitive deficits from iron deficiency anemia (IDA) in adult women, determine derangements in cerebral perfusion, vascular reactivity, functional connectivity, and blood brain barrier permeability in adult-onset IDA and relate them to neurocognitive deficits, as well as determine the reversibility and durability of both the physiologic and neurocognitive derangements by iron replacement therapy. All eligible subjects will be asked to provide informed consent before participating in the study.
Detailed Description
This is a trial with an observational and an interventional arm, in patients with moderate to severe anemia and control subjects. The main purposes of this study is to phenotype the scope of neurocognitive deficits from iron deficiency anemia (IDA) in adult women, determine derangements in cerebral perfusion, vascular reactivity, functional connectivity, and blood brain barrier permeability in adult-onset IDA and relate them to neurocognitive deficits, as well as determine the reversibility and durability of both the physiologic and neurocognitive derangements by iron replacement therapy. All eligible subjects will be asked to provide informed consent before participating in the study. Comprehensive cerebrovascular magnetic resonance imaging (MRI), bloodwork, patient reported outcomes, and neurocognitive testing will be collected from all subjects in the observational arm. 136 subjects total will be enrolled, 40 controls and 96 anemic subjects. The 96 eligible anemic subjects will then be invited to enroll in the interventional arm of the study. Anticipating a drop-out rate of 20%, 40 will be randomized into intravenous iron therapy, and 40 will be randomized into standard of care (oral iron via primary care). Repeated tests will be done at different timepoints to assess the effects and durability of iron therapy.
Investigators
John C. Wood
Professor
Children's Hospital Los Angeles
Eligibility Criteria
Inclusion Criteria
- •Observational arm:
- •Age between 16 and 60 years of age.
- •Any ethnicity.
- •Anemic group: hemoglobin ≤10.5 g/dl or hematocrit \<32% from finger prick or plethysmography test, or \<11 g/dl from venipuncture blood draw
- •Control group: hemoglobin \>13.2 g/dl or hematocrit \>39.6%
- •Interventional arm:
- •Criteria for observational component, plus
- •Iron deficiency anemia based upon attending hematologist interpretation of transferrin saturation, ferritin, and other ancillary labs including hs-CRP, MMA, hemoglobin electrophoresis
Exclusion Criteria
- •Observational arm:
- •Diabetes requiring medication.
- •Hypertension requiring medication.
- •Sleep disordered breathing requiring intervention.
- •Body mass index \>40 (morbid obesity)
- •Contraindications to MRI, including pacemaker, severe claustrophobia, pregnancy.
- •Known systemic inflammatory disease such as inflammatory bowel disease, systemic lupus erythematosus, or scleroderma.
- •Interventional arm:
- •Criteria for observational component, plus
- •Prior reaction to intravenous iron.
Arms & Interventions
Intravenous (IV) iron
This group will receive intravenous iron (Ferric Derisomaltose) in a single dose of 20 mg/kg (max individual dose of 1000 mg). The drug is administered as an infusion over 30 minutes. 3 months after the infusion, they will receive a 9-month supply of Novaferrum pill to be taken once a day.
Intervention: Ferric derisomaltose
Intravenous (IV) iron
This group will receive intravenous iron (Ferric Derisomaltose) in a single dose of 20 mg/kg (max individual dose of 1000 mg). The drug is administered as an infusion over 30 minutes. 3 months after the infusion, they will receive a 9-month supply of Novaferrum pill to be taken once a day.
Intervention: NovaFerrum
Outcomes
Primary Outcomes
Impact of iron deficiency anemia on regional cerebrovascular oxygen delivery (ml O2/100g/min).
Time Frame: Day 0 (observation arm)
Baseline impact of iron deficiency anemia on cerebrovascular oxygen delivery will be assessed by measuring cerebral blood flow and oxygen content through MRI (time-encoded arterial spin labelling) and peripheral blood sample
Impact of iron therapy on cerebrovascular flow reactivity (%SI change/%ETCO2) in people with iron deficiency anemia at day 365.
Time Frame: Day 365 post iron therapy
Impact of iron therapy on cardiovascular reserve in iron deficiency anemia will be assessed using MRI with blood oxygenation level dependent (BOLD) acquisition at day 365 post iron therapy.
Impact of iron therapy on total brain blood flow (ml blood/100g/min) in people with iron deficiency anemia at day 365
Time Frame: Day 365 post iron therapy
Phase contrast MRI will be assessed at day 365 post iron therapy to determine whether iron therapy affects total brain blood flow in subjects with iron deficiency anemia
Impact of iron deficiency anemia on visual-motor integration.
Time Frame: Day 0 (observation arm)
Visual-motor integration at baseline (day 0) will be assessed using Beery Buktenica Developmental Test of Visual-Motor Integration (6th Edition). Standardized scores with a mean of 100 and a standard deviation of 15 are used. Higher scores mean better performance.
Impact of iron deficiency anemia on cerebrovascular flow reactivity (%SI change/%ETCO2)
Time Frame: Day 0 (observation arm)
baseline MRI with blood oxygenation level dependent (BOLD) acquisition will be assessed in response to carbon dioxide exposure to determine whether iron deficiency anemia affects cerebrovascular reserve
Impact of iron therapy on cerebrovascular flow reactivity (%SI change/%ETCO2) in people with iron deficiency anemia at 90 days post iron therapy.
Time Frame: Day 90 post iron therapy
Impact of iron therapy on cardiovascular reserve in iron deficiency anemia will be assessed using MRI with blood oxygenation level dependent (BOLD) acquisition at 90 days post iron therapy.
Impact of iron therapy on regional cerebrovascular oxygen delivery (ml O2/100g/min) in iron deficiency anemia at day 365 post therapy.
Time Frame: Day 365 post iron therapy
Impact of iron therapy on cerebrovascular oxygen delivery will be assessed at day 365 by measuring cerebral blood flow and oxygen content through MRI (time-encoded arterial spin labelling) and peripheral blood sample in people with iron deficiency anemia
Impact of iron therapy on blood brain barrier permeability surface area product (ml H20/100g/min) in iron deficiency anemia will be assessed at 90 days.
Time Frame: Day 90 post iron therapy
PSA product using water-extraction-with phase- contrast-arterial-spin-tagging (WEPCAST) MRI will be assessed at 90 days post iron therapy to determine the impact of iron therapy on blood brain barrier permeability to water in patients with iron deficiency anemia.
Impact of iron deficiency anemia on cerebral metabolic rate of oxygen (ml O2/100g/min).
Time Frame: Day 0 (observation arm)
Baseline T2 relaxation under spin tagging (TRUST) acquisition via MRI will be used to assess any impact of iron deficiency anemia on cerebral metabolic rate of oxygen
Impact of iron therapy on visual-motor integration in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Visual-motor integration will be assessed using Beery Buktenica Developmental Test of Visual-Motor Integration (6th Edition) at day 365 post iron-therapy. Standardized scores with a mean of 100 and a standard deviation of 15 are used. Higher scores mean better performance.
Impact of iron therapy on sustained attention in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Sustained attention will be assessed using Conners' Continuous Performance Test (3rd Edition) at day 365 post iron-therapy. T-scores with a mean of 50 and a standard deviation of 10 are used. Higher scores mean worse performance.
Impact of iron therapy on the ability to inhibit cognitive interference in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
The ability to inhibit cognitive interference at day 365 post iron therapy will be assessed using Color-Word Interference Subtest from the Delis-Kaplan Executive Function System (D-KEFS). Scaled scores with a mean of 10 and a standard deviation of 3 are used. Higher scores mean better performance.
Impact of iron deficiency anemia on visuospatial memory
Time Frame: Day 0 (observation arm)
Visuospatial memory will be assessed at baseline (day 0) using Brief Visuospatial Memory Test-Revised (BVMT-R). T-scores with a mean of 50 and a standard deviation of 10 are used. Higher scores mean better performance.
Impact of iron deficiency anemia on cognitive flexibility and processing speed.
Time Frame: Day 0 (observation arm)
Cognitive flexibility and processing speed will be assessed at baseline (day 0) using NIH Toolbox: Dimensional Change Card Sort and Pattern Comparison Processing Speed. Standard scores with a mean of 100 and a standard deviation of 15 are used. Higher scores mean better performance.
Impact of iron deficiency anemia on emotional health
Time Frame: Day 0 (observation arm)
Emotional health will be assessed by using NIH toolbox emotion battery at baseline. T-scores with a mean of 50 and a standard deviation of 10 are used. Higher scores mean higher number/frequency of symptoms.
Impact of iron therapy on regional cerebrovascular oxygen delivery (ml O2/100g/min) in iron deficiency anemia at day 90 post therapy
Time Frame: Day 90 post-iron-therapy
Impact of iron therapy on cerebrovascular oxygen delivery will be assessed at day 90 by measuring cerebral blood flow and oxygen content through MRI (time-encoded arterial spin labelling) and peripheral blood sample in people with iron deficiency anemia.
Impact of iron deficiency anemia on total brain blood flow (ml blood/100g/min).
Time Frame: Day 0 (observation arm)
Phase contrast MRI will be assessed to determine whether iron deficiency anemia affects total brain blood flow at baseline
Impact of iron therapy on total brain blood flow (ml blood/100g/min) in people with iron deficiency anemia at day 90
Time Frame: Day 90 post iron therapy
Phase contrast MRI will be assessed at day 90 post iron therapy to determine whether iron therapy affects total brain blood flow in subjects with iron deficiency anemia
Impact of iron deficiency anemia on fine motor control.
Time Frame: Day 0 (observation arm)
Fine motor control will be assessed at baseline (day 0) using Reitan Finger Tapping. Z scores with a mean of zero and a standard deviation of one are used. Higher scores mean better performance.
Impact of iron therapy on visuospatial memory in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Visuospatial memory will be assessed at day 365 post iron therapy using Brief Visuospatial Memory Test-Revised (BVMT-R). T-scores with a mean of 50 and a standard deviation of 10 are used. Higher scores mean better performance.
Impact of iron deficiency anemia on blood brain barrier permeability surface area product (ml H20/100g/min)
Time Frame: Day 0 (observation arm)
baseline PSA product using water-extraction-with phase- contrast-arterial-spin-tagging (WEPCAST) MRI will be assessed to determine whether iron deficiency anemia affects blood brain barrier permeability to water
Impact of iron therapy on blood brain barrier permeability surface area product (ml H20/100g/min) in iron deficiency anemia will be assessed again at day 365.
Time Frame: Day 365 post iron therapy
PSA product using water-extraction-with phase- contrast-arterial-spin-tagging (WEPCAST) MRI will be assessed at 365 days post iron therapy to determine the impact of iron therapy on blood brain barrier permeability to water in patients with iron deficiency anemia.
Impact of iron therapy on cerebral metabolic rate of oxygen (ml O2/100g/min) in people with iron deficiency anemia at day 90 post iron therapy.
Time Frame: Day 90 post iron therapy
T2 relaxation under spin tagging (TRUST) acquisition via MRI will be used to assess any impact of iron therapy on cerebral metabolic rate of oxygen in anemic subjects at day 90.
Impact of iron therapy on cerebral metabolic rate of oxygen (ml O2/100g/min) in people with iron deficiency anemia at day 365 post iron therapy.
Time Frame: Day 365 post iron therapy
T2 relaxation under spin tagging (TRUST) acquisition via MRI will be used to assess any impact of iron therapy on cerebral metabolic rate of oxygen in anemic subjects at day 365.
Impact of iron deficiency anemia on sustained attention.
Time Frame: Day 0 (observation arm)
Sustained attention at baseline (day 0) will be assessed using Conners' Continuous Performance Test (3rd Edition) at day 90 post iron-therapy. T-scores with a mean of 50 and a standard deviation of 10 are used. Higher scores mean worse performance.
Impact of iron deficiency anemia on working memory function.
Time Frame: Day 0 (observation arm)
Working memory function at baseline (day 0) will be assessed using Digit Span, Coding, and Symbol Search Subtests from Wechsler Adult Intelligence Scale-Fourth Edition (WAIS-IV). Scaled scores with a mean of 10 and a standard deviation of 3 are used. Higher scores mean better performance.
Impact of iron therapy on working memory function in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Working memory function will be assessed at day 365 post iron therapy using Digit Span, Coding, and Symbol Search Subtests from Wechsler Adult Intelligence Scale-Fourth Edition (WAIS-IV). Scaled scores with a mean of 10 and a standard deviation of 3 are used. Higher scores mean better performance.
Impact of iron therapy on list learning and recall task in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
List learning and recall task will be assessed at day 365 post iron therapy using California Verbal Learning Test-Third Edition (CVLT-3). Z scores with a mean of zero and a standard deviation of 1 are used. Higher scores mean better performance.
Impact of iron therapy on general intellectual functioning, verbal and nonverbal abilities in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
General intellectual functioning, verbal and nonverbal abilities will be assessed at day 365 post iron therapy using Wechsler Abbreviated Scale of Intelligence-Second Edition (WASI-2). T scores with a mean of 50 and a standard deviation of 10 are used for the subtests, with standard scores (mean of 100 and standard deviation of 15) used for composite scores. Higher scores mean better performance.
Impact of iron therapy on cognitive flexibility and processing speed in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Cognitive flexibility and processing speed will be assessed at day 365 post iron therapy using NIH Toolbox: Dimensional Change Card Sort and Pattern Comparison Processing Speed. Standard scores with a mean of 100 and a standard deviation of 15 are used. Higher scores mean better performance.
Impact of iron deficiency anemia on the ability to inhibit cognitive interference
Time Frame: Day 0 (observation arm)
The ability to inhibit cognitive interference at baseline (day 0) will be assessed using Color-Word Interference Subtest from the Delis-Kaplan Executive Function System (D-KEFS). Scaled scores with a mean of 10 and a standard deviation of 3 are used. Higher scores mean better performance.
Impact of iron therapy on fine motor control in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Fine motor control will be assessed at day 365 post iron therapy using Reitan Finger Tapping. Z scores with a mean of zero and a standard deviation of one are used. Higher scores mean better performance.
Impact of iron therapy on emotional health in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Emotional health will be assessed at day 365 post iron therapy by using NIH toolbox emotion battery. T-scores with a mean of 50 and a standard deviation of 10 are used. Higher scores mean higher number/frequency of symptoms.
Impact of iron deficiency anemia on executive functions in day-to-day life.
Time Frame: Day 0 (observation arm)
Executive functions in day-to-day life will be assessed at baseline using the Behavior Rating Inventory of Executive Function 2 (BRIEF-2). T-scores with a mean of 50 and a standard deviation of 10 are used. Scores above T=65 may indicated problems.
Impact of iron deficiency anemia on general intellectual functioning, verbal and nonverbal abilities.
Time Frame: Day 0 (observation arm)
General intellectual functioning, verbal and nonverbal abilities will be assessed at baseline (day 0) using Wechsler Abbreviated Scale of Intelligence-Second Edition (WASI-2). T scores with a mean of 50 and a standard deviation of 10 are used for the subtests, with standard scores (mean of 100 and standard deviation of 15) used for composite scores. Higher scores mean better performance.
Impact of iron deficiency anemia on list learning and recall task
Time Frame: Day 0 (observation arm)
List learning and recall task will be assessed at baseline (day 0) using California Verbal Learning Test-Third Edition (CVLT-3). Z scores with a mean of zero and a standard deviation of 1 are used. Higher scores mean better performance.
Impact of iron therapy on executive functions in day-to-day life in people with iron deficiency anemia.
Time Frame: Day 365 post iron therapy
Executive functions in day-to-day life will be assessed at day 365 using the Behavior Rating Inventory of Executive Function 2 (BRIEF-2). T-scores with a mean of 50 and a standard deviation of 10 are used. Scores above T=65 may indicated problems.
Secondary Outcomes
- Impact of iron deficiency anemia on MRI measured brain iron in deep brain nuclei, hippocampus, whole brain grey and white matter.(Day 0 (observation arm))
- Screening for Restless Legs Syndrome (RLS) at baseline(Day 0 (observation arm))
- Changes in patient reported outcomes of health and quality of life will be assessed over a period of 1 year post iron therapy.(Day 14 (for IV iron group only), Day 90, Day 180, Day 365)
- Patient reported outcomes of fatigue will be assessed at baseline.(Day 0 (observation arm))
- Acute impact of intravenous (IV) iron therapy on visuospatial memory in people with iron deficiency anemia.(Day 14 post IV iron therapy)
- Patient reported outcomes of health and quality of life will be assessed at baseline.(Day 0 (observation arm))
- Changes in patient reported outcomes of fatigue will be assessed over a period of 1 year post iron therapy.(Day 14 (for IV iron group only), Day 90, Day 180, Day 365)
- Changes in the impact of iron therapy on MRI measured brain iron in deep brain nuclei, hippocampus, whole brain grey and white matter.(Day 14 (for IV iron group only), Day 90, Day 365)
- Changes in hemoglobin and ferritin will be assessed to determine durability of hemoglobin and ferritin response to therapy from baseline to 1 year post iron therapy.(Day 0 (observation arm), Day 14 (for IV iron treated), Day 90, Day 180, Day 365)
- Changes in Restless Legs Syndrome (RLS) as an effect of iron therapy in people with iron deficiency anemia will be assessed post iron therapy.(Day 14 (for intravenous iron group only), Day, 90, Day 180, Day 365)
- Acute impact of intravenous (IV) iron therapy on list learning and recall task in people with iron deficiency anemia.(Day 14 post IV iron therapy)