Contrast-Enhanced MRI for Tissue Perfusion · 2018. 12. 27. · 1 of 95 Contrast-Enhanced MRI for...

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Contrast-Enhanced MRI

for Tissue Perfusion

Hsiao-Wen Chung (鍾孝文), Ph.D., Professor

Dept. Electrical Engineering, National Taiwan Univ.

Dept. Radiology, Tri-Service General Hospital

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Perfusion MRI with Gd

• I have to assume that you are familiar

with T1 contrast agents in MRI (Gd-

DTPA or the like)

– although I never taught relaxation

mechanism & contrast agent …

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What Is Perfusion ?

• Microcirculation, blood flow ...

• Not angiography though

• Capillary blood flow at tissue site

– Exchange of nutrients/wastes

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Meaning of Perfusion

?

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To “See” Capillary Flow

• Capillary diameter : 0.005 mm

– Current imaging does not see

(resolution limitation)

• Meaningless to see single capillary

– “Overall” evaluation of nutrient

exchange at tissue site

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Perfusion & Tracer

• Tracer kinetics

• Inject tracer into blood vessel

– Often intravenous injection

• Blood flow extrapolated by

following the tracer

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Tracer Distribution (a Time Function)

?

wash-in

wash-out

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What Does Curve Tell ?

• No obvious change in signal: ischemia,

upstream occlusion …

• Large change: abnormal blood volume …

• Slow wash-in: upstream narrowing (stenosis),

collateral flow …

• Slow wash-out: tortuous vessels, increased

permeability …

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Perfusion from Tracer-Time Curve

Two typical types of ischemia

Time

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Normal tissue

Low blood volume

Long transit time

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Perfusion Maps

• Get time curve for every pixel

• Calculate blood volume, transit

time, blood flow for every pixel

• Map perfusion parameters back

to form new images

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Perfusion from Tracer-Time Curve

Fairly close although not too accurate

area ~ blood volume

width ~ transit time

height ~ blood flow

Time

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Distribution of Cerebral Blood Volume

Allows rapid lesion/normal comparison

Siemens Vision+ 1.5T

0.2 mM/Kg Gd-DTPA

EPI (TR=1000, TE=60)

128x128, 3 slices

Bright means more

blood

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Distribution of Mean Transit Time

Allows rapid lesion/normal comparison

Siemens Vision+ 1.5T

0.2 mM/Kg Gd-DTPA

EPI (TR=1000, TE=60)

128x128, 3 slices

Bright means slower

passage

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Typical Perfusion Imaging

• (Not necessarily MRI)

• Intravenous tracer injection

• Dynamic image scanning

• Calculate perfusion parameters

• Form parameter images

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Perfusion MRI

• Contrast + dynamic scan

– T1-weighted

– T2*-weighted

• Arterial spin labeling

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Perfusion MRI

• Contrast + dynamic scan

– T1-weighted

– T2*-weighted

• Arterial spin labeling

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Ha ! Too Simple !

• Intravenous Gd-DTPA injection

• T1WI scanned many times

• Gd flows in brightened, flows out

darkened

• … not that straightforward though

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Capillary Permeability

• Contrast has relatively large chelate

that may not enter tissue rapidly

• In the case of low blood volume

fraction, T1 enhancement very small

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What Is Chelate Then ?

• Molecule that surrounds the

heavy metal ion

• Isolate toxicity

• Avoid heavy metal poisoning

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Gd-DTPA (Magnevist) Structure

Safe and still effective in enhancing relaxation

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Some FDA Approved Gd Chelates

Still large compared capillary permeability

Gd-DTPA (Magnevist) Gd-DOTA (Dotarem)

Gd-DTPA-BMA (Omniscan) Gd-HP-DO3A (Prohance)

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Diffusible Tracer

But not completely freely diffusible

capillary wall

DTPA DTPA

DTPA

capillary wall

ca

pilla

ry

DTPA

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T1 Effect Restricted within Capillaries

Low volume fraction small T1 enhancement

capillaries

image voxel

tissue

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Capillary Permeability

• Contrast has relatively large chelate

that may not enter tissue rapidly

• In the case of low blood volume

fraction, T1 enhancement very small

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Solution

• Extend image scan to permit multiple

(actually many) circulations

• Contrast gradually enters/leaves tissue

• T1WI continuously follow for ~10 min

– Scan & injection do not need to be fast

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Example: Breast

• Malignant tumor often contains

highly permeable neovasculature

– Called “angiogenesis”

• Perfusion MRI uses wash-in & wash-

out information for tumor malignancy

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Normal vs. Tumor Signal-Time Curves

min min

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Parameter Calculation

• Brix model (1991)

• Signal-time curve consists of 3

major parameters

• Blood volume, exchange rate,

(kidney) excretion rate

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Brix Perfusion Model (1991)

Assumption: exchange rate in equilibrium

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No Mean Transit Time

• Very long dynamic scan used

• How fast contrast agent passes

the tissue cannot be examined

• “Equilibrium phase”

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Clinical Applications

• Brain tissue with disrupted BBB

• Pituitary gland

• Femoral head, hip joint

• Breast imaging …

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That’s Low Blood Volume

• What about high blood volume fraction ?

• Example: lung

– Almost all air & capillaries (alveoli)

– Blood the only MR signal source

• Obvious signal change during first-pass

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But T1WI Scan Time …

• Gradient echo: tens of seconds

• Spin echo: some minutes

• One circulation: ~22 sec

• T1WI often too slow for first-pass

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First-Pass T1 Perfusion

• Only for specific tissue (lung)

• New fast-scan T1WI technique

• Limited slice coverage

• Rapid (bolus) contrast injection

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Lung Perfusion MRI Example

Pre-contrast Post-contrast

0 10 20 30 40 50 60-5

0

5

10

15

20

25

30

35

wash-in wash-out

2nd pass

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Parameter Calculation

• Gamma-variate function

• Signal-time curve consists of 2

major parameters

• Blood volume, mean transit time

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Perfusion from Tracer-Time Curve

Fairly close although not too accurate

area ~ blood volume

width ~ transit time

height ~ blood flow

Time

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Perfusion Parameters

• Blood volume = integration of

(area under) first-pass curve

• Mean transit time = normalized

first-moment (centroid)

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Plus Variations in “Arrival Time”

Most normal perfusion curves are like this

Time

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No Permeability

• Very short time in first-pass

transit little contrast leakage

– First-pass: 10-15 sec

– Complete circulation: ~22 sec

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Diffusible Tracer

But not completely freely diffusible

capillary wall

DTPA DTPA

DTPA

capillary wall

ca

pilla

ry

DTPA

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About Injection Speed …

Ideal vs. nonideal bolus injection

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Mean Transit Time from the Curve

Gd in “upstream + tissue” both considered

Fast wash-in? Fast upstream?

Slow wash-in? Slow upstream?

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Gd Signal-Time Curve

• Upstream & tissue combined

• De-convolution to obtain pure

tissue perfusion … (complicated)

– Like “x = z/y” from “xy = z”

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Clinical Applications

• Tumor angiogenesis

• Pulmonary stenosis

• Pulmonary embolism

• Other lung perfusion evaluation

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Healthy Male Lung Perfusion

rMTT rPBV

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Lung Cancer

rMTT rPBV

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Pulmonary Stenosis

rMTT rPBV

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Note: Lung MRI

• Lung MRI itself is challenging

– Low proton density, short T2

• Sequence with TE < 1 ms needed

• Shown are research examples

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Note: First-Pass Gd

• Contrast (& blood) just “passes”

the tissue capillaries

• Don’t know if “enters” tissue

• Blood flow unequal to perfusion

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Another Example: Liver

• Malignant tumor: recruit vessels

in hepatic artery territory

• Blood from portal vein fine

• Dynamic Gd imaging for hepatic

arterial & portal venous phases

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Hepatocellular Carcinoma MRI

Pre Gd Arterial phase

VIBE MIP Portal venous phase

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Note: Perfusion?

• Fast dynamic imaging doesn’t

show blood perfuse into tissue

• Sometimes just properly called

dynamic contrast-enhanced MRI

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Perfusion MRI

• Contrast + dynamic scan

– T1-weighted

– T2*-weighted

• Arterial spin labeling

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Intravascular Contrast

• Contrast simply does not leave

low-volume-fraction capillaries

– Brain (blood-brain barrier)

• Use first-pass T2* perfusion MRI

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Diffusible & Non-diffusible Tracer

Contrast agent completely non-diffusible

capillary wall

DTPA DTPA

DTPA DTPA

capillary wall

ca

pilla

ry

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T1 Effect Restricted within Capillaries

Low volume fraction small T1 enhancement

capillaries

image voxel

tissue

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2 Effects of Gd Contrast

• T1: shortened bright on T1WI

– Within vessel, small range

• T2*: shortened dark on T2*WI

– Near vessel, wide range

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Unpaired Electron of Gd Distorts Bo

Larmor freq altered for nearby protons

Bo

H2O

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MR Contrast Agents

• Gd: paramagnetic agent

– Shorten T1 (with Gd presence)

– Distorts Bo homogeneity

(wherever “close to” Gd)

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Range of T1 Influence

Confined within capillaries with intact BBB

capillary

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range of Bo alteration

Range of T2* Influence

About 62% water molecules affected

capillary

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T2* Perfusion MRI

• Use paramagnetic susceptibility

of Gd to distort Bo & shorten T2*

• Dynamic susceptibility-contrast

perfusion-weighted MRI

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T2*WI in Brain Perfusion

• Ideal first-pass perfusion MRI

• Fast scan + T2* weighting EPI

– 6+ slices each second

• Bolus Gd injection

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Signal Changes as a Function of Time

5 sec 6 sec 7 sec 8 sec

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Signal Changes as a Function of Time

9 sec 11 sec 13 sec 15 sec

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Signal Changes as a Function of Time

17 sec 19 sec 21 sec 23 sec

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Signal Changes as a Function of Time

5 sec 11 sec 17 sec 23 sec

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Wash-in & Wash-out of T2*WI Curve

Signal drops when Gd arrives

Time

Sig

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Parameter Calculation

• Gamma-variate function

– Same as first-pass T1

• Blood volume, mean transit time

• After conversion from T2* to [Gd]

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Wash-in & Wash-out of T2*WI Curve

Signal drops when Gd arrives

Time

Sig

na

l in

ten

sit

y

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Perfusion from Tracer-Time Curve

Fairly close although not too accurate

area ~ blood volume

width ~ transit time

height ~ blood flow

Time

Tra

ce

r c

on

ce

ntr

ati

on

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Perfusion Parameters

• Blood volume = integration of

(area under) first-pass curve

• Mean transit time = normalized

first-moment (centroid)

• Same as first-pass T1

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Plus Variations in “Arrival Time”

Most normal perfusion curves are like this

Time

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Parameter Names …

• rCBV = cerebral blood volume

• rMTT = mean transit time

• rCBF = cerebral blood flow

• “r” for “relative”

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Why Only Relative?

Inter-subject comparison not allowed

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Intra-Subject Perfusion Map Depiction

rCBV rMTT rCBF

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T2* Brain Perfusion MRI

• Good sensitivity

– 30 ~ 60% signal change

• First-pass suffices short scan

• Routinely used clinically

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Clinical Applications

• Ischemic stroke

– Infarct, therapeutic decision

• Brain tumor

– Angiogenesis, biopsy guide

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Perfusion MRI for Ischemic Stroke

Angio CT T1+Gd

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Perfusion MRI for Ischemic Stroke

DWI (b=1000) ADC map

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Perfusion MRI for Ischemic Stroke

rMTT map rCBV map

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Ischemic Stroke

• Diffusion negative: cytotoxic

edema not commenced yet

• Likely reversible process

• Large CBV + long MTT: collateral

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Diagnosis Affects Therapy

rCBV

13 hr after

IA rtPA

5-hr onset

rMTT

rCBV

rMTT

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Perfusion MRI for Glioma

T2 FLAIR rCBV map

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Perfusion MRI for Glioma

F/U at 7 months

F/U at 1 year

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Note: DSC Perfusion MRI

• Also first-pass transit only

• Contrast (& blood) just “passes”

the tissue capillaries

• Blood flow unequal to perfusion

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Note: Abnormal Curves

• Signal drop without returning to baseline ?

– Gd does not flow out ??

• Tortuous vessels? Permeable vessels?

Microvascular structure?

• Still under debate & investigation

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Perfusion MRI for Glioma

T1WI + Gd rCBV map

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Gd Concentration-Time Curve

Likely reflect tortuous neovasculature

0

0.2

0.4

0.6

0.8

1

1.2

0 20 40 60

Time after bolus arrival (seconds)

Co

ntr

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ce

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ation

(arb

itra

ry u

nits)

lesion

normal

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Gd Perfusion MRI

• Contrast + dynamic scan

– T1-weighted equilibrium phase

– T1-weighted first-pass

– T2*-weighted first-pass

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Which Method to Use?

• Depends on tissue capillary

characteristics

– Brain T2*WI used routinely

• Not necessarily for other tissues

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Perfusion MRI

• Contrast + dynamic scan

– T1-weighted

– T2*-weighted

• Arterial spin labeling

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Perfusion MRI with ASL

• Arterial spin labeling

– RF pulse to “label” the blood

– No injection needed

• We’ll leave it for other semesters!

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Contrast-Enhanced MRI

for Tissue Perfusion

Hsiao-Wen Chung (鍾孝文), Ph.D., Professor

Dept. Electrical Engineering, National Taiwan Univ.

Dept. Radiology, Tri-Service General Hospital