Date | May 2017 | Marks available | 1 | Reference code | 17M.3.HL.TZ1.13 |
Level | Higher level | Paper | Paper 3 | Time zone | Time zone 1 |
Command term | Explain | Question number | 13 | Adapted from | N/A |
Question
In the context of nuclear magnetic resonance (NMR) imaging explain the role of
Outline why the fracture in a broken bone can be seen in a medical X-ray image.
The diagram shows X-rays incident on tissue and bone.
The thicknesses of bone and tissue are both 0.054 m.
The intensity of X-rays transmitted through bone is Ib and the intensity transmitted through tissue is It.
The following data are available.
Mass absorption coefficient for bone = mass absorption
coefficient for tissue = 1.2 × 10–2\(\,\)m2\(\,\)kg–1
Density of bone = 1.9 × 103 kg\(\,\)m–3
Density of tissue = 1.1 × 103 kg\(\,\)m–3
Calculate the ratio \(\frac{{{I_{\text{b}}}}}{{{I_{\text{t}}}}}\).
the large uniform magnetic field applied to the patient.
the radio-frequency signal emitted towards the patient.
the non-uniform magnetic field applied to the patient.
Markscheme
bone and tissue absorb different amounts of X-rays
OR
bone and tissue have different attenuation coefficients
so boundaries and fractures are delineated in an image
[2 marks]
\(\frac{{{I_{{\text{bone}}}}}}{{{I_{{\text{tissue}}}}}} = \frac{{{I_0}{{\text{e}}^{ - {\mu _{\text{b}}}x}}}}{{{I_0}{{\text{e}}^{ - {\mu _{\text{t}}}x}}}} = {{\text{e}}^{ - \left( {{\mu _{\text{b}}} - {\mu _{\text{t}}}} \right)x}}\)
\(\frac{{{I_{{\text{bone}}}}}}{{{I_{{\text{tissue}}}}}} = {{\text{e}}^{ - 1.2 \times {{10}^{ - 2}} \times \left( {1.9 - 1.1} \right) \times {{10}^3} \times 5.4 \times {{10}^{ - 2}}}}\)
\(\frac{{{I_{{\text{bone}}}}}}{{{I_{{\text{tissue}}}}}} = 0.60\)
[3 marks]
to split the energy level of protons in the body
OR
to cause protons in the body to align with the field / precess at Larmor frequency
[1 mark]
to force/excite protons that are in the spin up/parallel state
into a transition to the spin down/antiparallel state
[2 marks]
the emitted radio frequency signal has a frequency that depends on the magnetic field
with a gradient field different parts of the body have different frequencies and so can be identified
[2 marks]