EXAM #7 — MODULE 7 Flashcards
Patient placed in magnetic bore: longitudinal axis of body parallel to longitudinal magnetic field
- _____ axis: from right to left
- _____ axis: from anterior to posterior
- _____ axis: along longitudinal axis (from head to toe)
* Static magnetic field strength is fairly _____: all protons in body precess w/ _____ frequency
Patient placed in magnetic bore: longitudinal axis of body parallel to longitudinal magnetic field
- X axis: from right to left
- Y axis: from anterior to posterior
- Z axis: along longitudinal axis (from head to toe)
* Static magnetic field strength is fairly homogeneous: all protons in body precess w/ Larmor frequency
To examine a specific slice:
Magnetic field strength can be varied along any axis to create a magnetic field _____: a progression of magnetic field strengths through the patient. Magnetic gradient is _____ over external magnetic field
- By using the Larmor equation: ωo=γβ it can be determined from which location (slice) within the patient the signal arises (fig 2.7 mic)
a. γ = _____ MHZ for hydrogen protons (constant)
b. β : magnetic field _____ and location (slice) within patient is established and known
c. ω : we know the _____ frequencies of protons in each slice since we know the location of each magnetic field strength in the gradient
To examine a specific slice: Magnetic field strength can be varied along any axis to create a magnetic field gradient: a progression of magnetic field strengths through the patient. Magnetic gradient is superimposed over external magnetic field
- By using the Larmor equation: ωo=γβ it can be determined from which location (slice) within the patient the signal arises (fig 2.7 mic)
a. γ = 42.5 MHZ for hydrogen protons (constant)
b. β : magnetic field strength and location (slice) within patient is established and known
c. ω : we know the precessional frequencies of protons in each slice since we know the location of each magnetic field strength in the gradient
To examine a specific slice:
- By turning on a gradient (slice selecting gradient) simultaneously to the RF pulse, we can match the RF pulse frequency to the equal proton precessional frequency: only protons in the slice that are precessing at the _____ frequency as the RF pulse will be excited to flip 90° or 180° and generate a _____ (fig 57, pg87).
Slice selecting gradient is turned _____ only during application of RF pulse
To examine a specific slice:
- By turning on a gradient (slice selecting gradient) simultaneously to the RF pulse, we can match the RF pulse frequency to the equal proton precessional frequency: only protons in the slice that are precessing at the same frequency as the RF pulse will be excited to flip 90° or 180° and generate a signal (fig 57, pg87).
Slice selecting gradient is turned on only during application of RF pulse
To examine a specific slice:
By knowing the _____ frequency in each location (slice) across the gradient and by knowing the frequency of the _____, we therefore know the slice which the RF pulse is exciting and which is generating the signal
To examine a specific slice:
By knowing the precessional frequency in each location (slice) across the gradient and by knowing the frequency of the RF pulse, we therefore know the slice which the RF pulse is exciting and which is generating the signal
Orientation of magnetic field gradient, selected by technologist, determines in which orthogonal plane the excited slice will lie and in which plane the image will be
- _____ axis: sagittal slice and image
- _____ axis: coronal slice and image
- _____ axis: transverse (axial) slice and image
Orientation of magnetic field gradient, selected by technologist, determines in which orthogonal plane the excited slice will lie and in which plane the image will be
- X axis: sagittal slice and image
- Y axis: coronal slice and image
- Z axis: transverse (axial) slice and image
Determining Slice Thickness - 2 methods:
- The wider the range of RF frequencies (band width) introduced concurrently with the slice selecting magnetic gradient, the _____ the slice (thinner RF bandwidth-thinner slice)
* RF frequencies will match precessional frequencies of protons over a broader thickness of the magnetic gradient, thus excite a _____ slice of protons
Determining Slice Thickness - 2 methods:
- The wider the range of RF frequencies (band width) introduced concurrently with the slice selecting magnetic gradient, the wider the slice (thinner RF bandwidth-thinner slice)
* RF frequencies will match precessional frequencies of protons over a broader thickness of the magnetic gradient, thus excite a thicker slice of protons
Determining Slice Thickness - 2 methods:
- The steeper the slice selecting magnetic gradient (ex: the more difference in magnetic field strength between the feet and the head), the _____ the slice (transverse slice) if RF bandwidth remains constant
* this occurs because in a steeper magnetic gradient over the same length of anatomy many more intervals of magnetic field strengths must fit into a fixed length, thus each magnetic field strength width (each precessional width) must be _____
Determining Slice Thickness - 2 methods:
- The steeper the slice selecting magnetic gradient (ex: the more difference in magnetic field strength between the feet and the head), the thinner the slice (transverse slice) if RF bandwidth remains constant
* this occurs because in a steeper magnetic gradient over the same length of anatomy many more intervals of magnetic field strengths must fit into a fixed length, thus each magnetic field strength width (each precessional width) must be thinner
Localizing a Signal from a point within a slice:
- RF pulse applied concurrently with slice selecting gradient (ex: along z-axis) gets all protons in one (transverse) slice precessing in phase at the _____ frequency
Localizing a Signal from a point within a slice:
- RF pulse applied concurrently with slice selecting gradient (ex: along z-axis) gets all protons in one (transverse) slice precessing in phase at the same frequency
Localizing a Signal from a point within a slice:
- After RF pulse turned off, another magnetic gradient, the _____ encoding magnetic gradient (readout gradient), is _____ on the external magnetic field (after the slice selection gradient) and _____ during signal collection (ex: along x-axis of the slice) - causes protons in different sagittal columns from R to L across the slice to precess with different decreasing frequencies and give off signals with different decreasing frequencies proportional to magnetic field strength of that column (fig 59)
Determines origin of signal from a certain _____ (specific location in column unknown at this point: all protons in one column in same magnetic field strength & precess w/ same frequency)
Localizing a Signal from a point within a slice:
- After RF pulse turned off, another magnetic gradient, the frequency encoding magnetic gradient (readout gradient), is superimposed on the external magnetic field (after the slice selection gradient) and maintained during signal collection (ex: along x-axis of the slice) - causes protons in different sagittal columns from R to L across the slice to precess with different decreasing frequencies and give off signals with different decreasing frequencies proportional to magnetic field strength of that column (fig 59)
Determines origin of signal from a certain column (specific location in column unknown at this point: all protons in one column in same magnetic field strength & precess w/ same frequency)
Localizing a Signal from a point within a slice:
- Also after the RF pulse is turned off, another magnetic gradient, the _____ encoding magnetic gradient, is turned on for a very short time (ex: along y-axis of the slice), then turned off - causes protons and their signals at each vertical point along the column to precess out of phase (i.e.: to be at a different point in the phase cycle at each point in the column in which the phase encoding magnetic gradient field differs) , but at the same frequency in any one phase enc _____ (in proportion to the frequency encoding magnetic field) (fig 60, pg 93)
- Thus signal frequencies from column to column vary, but are the same in any one column; signals from different points (heights) in the same column have different phases
* This determines the specific point of origin of a signal within a certain column in a slice: system can differentiate each pixel’s different unique frequency and phase (each pixel has its own unique (x,y) address)
Localizing a Signal from a point within a slice:
- Also after the RF pulse is turned off, another magnetic gradient, the phase encoding magnetic gradient, is turned on for a very short time (ex: along y-axis of the slice), then turned off - causes protons and their signals at each vertical point along the column to precess out of phase (i.e.: to be at a different point in the phase cycle at each point in the column in which the phase encoding magnetic gradient field differs) , but at the same frequency in any one phase enc row (in proportion to the frequency encoding magnetic field) (fig 60, pg 93)
- Thus signal frequencies from column to column vary, but are the same in any one column; signals from different points (heights) in the same column have different phases
* This determines the specific point of origin of a signal within a certain column in a slice: system can differentiate each pixel’s different unique frequency and phase (each pixel has its own unique (x,y) address)
- Using the Fourier transformation, a mathematical process, a computer analyzes how much signal (intensity) of a specific _____ (column) and _____ (row or point in the column) is generated
- a signal of a certain intensity can be assigned to a specific location (column and row) within the slice and an image can thus be reconstructed through the Fourier transform
- Using the Fourier transformation, a mathematical process, a computer analyzes how much signal (intensity) of a specific frequency (column) and phase (row or point in the column) is generated
- a signal of a certain intensity can be assigned to a specific location (column and row) within the slice and an image can thus be reconstructed through the Fourier transform
Hydrogen Nucleii: preferred for MR imaging
- consist of _____ proton
- occur in large abundance throughout the body
- give the _____ intense (strongest) signal compared to other nucleii in a magnetic field
- have an _____ number of protons: an extra will always be left in parallel orientation, creating a net magnetization vector (a magnetic moment)
Hydrogen Nucleii: preferred for MR imaging
- consist of 1 proton
- occur in large abundance throughout the body
- give the most intense (strongest) signal compared to other nucleii in a magnetic field
- have an odd number of protons: an extra will always be left in parallel orientation, creating a net magnetization vector (a magnetic moment)
MRI Hardware
- magnetic field strength measured in Tesla: 1 Tesla = _____ Gauss (1T = 1G)
- field strength range for clinical application: typically _____ T to _____ T
MRI Hardware
- magnetic field strength measured in Tesla: 1 Tesla = 10,000 Gauss (1T = 1G)
- field strength range for clinical application: typically .5 T to 2.0 T
magnet types:
a. permanent magnets
- _____ loses magnetism
- requires no energy/power to _____ magnetic field
- _____ field strength
- extremely _____
magnet types:
a. permanent magnets
- never loses magnetism
- requires no energy/power to maintain magnetic field
- limited field strength
- extremely heavy
magnet types:
resistive magnets:
- _____ current passed through wire loops: induces magnetic field
- thus also called _____
- achieve _____ magnetic field strength than permanent magnets
- require electrical power to _____ magnetic field
- resistance in conductive wire _____ generates heat: require cooling
magnet types:
resistive magnets:
- electrical current passed through wire loops: induces magnetic field
- thus also called electromagnets
- achieve higher magnetic field strength than permanent magnets
- require electrical power to maintain magnetic field
- resistance in conductive wire loops generates heat: require cooling
