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'''Magnetic resonance imaging''' (also known as '''Nuclear Magnetic Resonance imaging''' or as an '''MRI scan''') is a [[non-destructive imaging]] technique with a wide range of applications in the [[materials science]]s and [[life sciences]], including [[diagnostic imaging]] and [[neuroimaging]]. It employs the principle of [[nuclear magnetic resonance]] and is thus, in essence, a variant of [[NMR spectroscopy]] in which the focus is on providing information regarding the distribution of [[nucleus|nuclei]] in [[space]]. The information regarding the spatial distribution of nuclei is usually provided in the form of a plot showing the variation of the density (number of nuclei of interest per unit volume) as a function of the position. In the case of medical MRI, the most commonly used nucleus is the nucleus of the [[hydrogen]] [[atom]]. Most biomedical MR images are essentially plots showing the distribution of [[water]] in the [[human body|body]] because water constitutes about 70% of the total body weight of [[human]] beings. The [[technology]] developed as a result of research on the effect of [[gravitation|gravity]] on [[light]] by [[Robert Pound]]. | |||
{{TOC|right}} | |||
==Classification== | ==Classification== | ||
* [[Echo-planar imaging]] allows much faster acquisition of images. | * [[Echo-planar imaging]] allows much faster acquisition of images. | ||
* [[Functional magnetic resonance imaging]] uses echo-planar imaging and measures changes in oxygenation status of hemoglobin in response to specific sensory or motor stimulation.<ref name="PMID7825767">Le Bihan D, Jezzard P, Haxby J, Sadato N, Rueckert L, Mattay V. Functional magnetic resonance imaging of the brain. Ann Intern Med. 1995 Feb 15;122(4):296-303. PMID 7825767</ref><ref name="PMID9504943">Gilman S. [http://content.nejm.org/cgi/content/full/338/12/812 Imaging the brain. First of two parts.] N Engl J Med. 1998 Mar 19;338(12):812-20. PMID 9504943</ref><ref name="PMID9516225">Gilman S. [http://content.nejm.org/cgi/content/full/338/13/889 Imaging the brain. Second of two parts]. N Engl J Med. 1998 Mar 26;338(13):889-96. PMID 9516225</ref> | * [[Functional magnetic resonance imaging]] uses echo-planar imaging and measures changes in oxygenation status of hemoglobin in response to specific sensory or motor stimulation.<ref name="PMID7825767">Le Bihan D, Jezzard P, Haxby J, Sadato N, Rueckert L, Mattay V. Functional magnetic resonance imaging of the brain. Ann Intern Med. 1995 Feb 15;122(4):296-303. PMID 7825767</ref><ref name="PMID9504943">Gilman S. [http://content.nejm.org/cgi/content/full/338/12/812 Imaging the brain. First of two parts.] N Engl J Med. 1998 Mar 19;338(12):812-20. PMID 9504943</ref><ref name="PMID9516225">Gilman S. [http://content.nejm.org/cgi/content/full/338/13/889 Imaging the brain. Second of two parts]. N Engl J Med. 1998 Mar 26;338(13):889-96. PMID 9516225</ref> | ||
* [[Magnetic resonance angiography]] | * [[Magnetic resonance angiography]] (perfusion-weighted imaging) | ||
* [[ | * [[NMR spectroscopy]]<ref>Fisher M, Prichard JW, Warach S. New magnetic resonance techniques for acute ischemic stroke. JAMA. 1995 Sep 20;274(11):908-11. PMID 7674506</ref> | ||
* [[Magnetic resonance microscopy]] - concerned with imaging at resolutions around or below the [[resolution limit]] if the [[human eye]] (about 100µm) | |||
* [[Localized spectroscopy]] - combines MR spectroscopy and MR imaging by providing spectroscopic information from specific spatial locations within the sample | |||
* [[Chemical-shift imaging]] - combines [[NMR spectroscopy]] and MR imaging by providing information about the variation in the spatial distribution of nuclei having spectroscopically distinguishable values of chemical shifts | |||
* [[Cine magnetic resonance imaging]] is primarily used in cardiology. | * [[Cine magnetic resonance imaging]] is primarily used in cardiology. | ||
* [[Diffusion magnetic resonance imaging]] usually uses echo-planar imaging and measures changes in the apparent diffusion coefficient (ADC). | * [[Diffusion magnetic resonance imaging]] (diffusion-weighted imaging) usually uses echo-planar imaging and measures changes in the apparent diffusion coefficient (ADC). | ||
==Physical principles== | ==Physical principles== | ||
In contrast to [[x-ray computed tomography]] which is based on the density of electrons in tissues, MRI is based on several properties of protons.<ref name="PMID6506686">Hendee WR, Morgan CJ. [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=6506686 Magnetic resonance imaging. Part I--physical principles]. West J Med. 1984 Oct;141(4):491-500. PMID 6506686</ref><ref name="PMID6516335">Hendee WR, Morgan CJ. [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=6516335 Magnetic resonance imaging. Part II--Clinical applications]. West J Med. 1984 Nov;141(5):638-48. PMID 6516335</ref><ref name="PMID8433731">Edelman RR, Warach S. [http://content.nejm.org/cgi/content/full/328/10/708 Magnetic resonance imaging - First of Two Parts]. N Engl J Med. 1993 Mar 11;328(10):708-16. PMID 8433731</ref><ref name"PMID8369029">Edelman RR, Warach S. [http://content.nejm.org/cgi/content/full/328/11/785 Magnetic resonance imaging - Second of Two Parts]. N Engl J Med. 1993 Mar 18;328(11):785-91. PMID 8369029</ref><ref name="PMID11777806">Berger A. [http://www.bmj.com/cgi/content/full/324/7328/35 Magnetic resonance imaging]. BMJ. 2002 Jan 5;324(7328):35. PMID 11777806</ref | In contrast to [[x-ray computed tomography]] which is based on the density of electrons in tissues, MRI is based on several properties of protons.<ref name="PMID6506686">Hendee WR, Morgan CJ. [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=6506686 Magnetic resonance imaging. Part I--physical principles]. West J Med. 1984 Oct;141(4):491-500. PMID 6506686</ref><ref name="PMID6516335">Hendee WR, Morgan CJ. [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=6516335 Magnetic resonance imaging. Part II--Clinical applications]. West J Med. 1984 Nov;141(5):638-48. PMID 6516335</ref><ref name="PMID8433731">Edelman RR, Warach S. [http://content.nejm.org/cgi/content/full/328/10/708 Magnetic resonance imaging - First of Two Parts]. N Engl J Med. 1993 Mar 11;328(10):708-16. PMID 8433731</ref><ref name"PMID8369029">Edelman RR, Warach S. [http://content.nejm.org/cgi/content/full/328/11/785 Magnetic resonance imaging - Second of Two Parts]. N Engl J Med. 1993 Mar 18;328(11):785-91. PMID 8369029</ref><ref name="PMID11777806">Berger A. [http://www.bmj.com/cgi/content/full/324/7328/35 Magnetic resonance imaging]. BMJ. 2002 Jan 5;324(7328):35. PMID 11777806</ref> | ||
Atoms with an odd number of [[nucleon]]s (protons and neutrons), such as [[hydrogen]] and [[carbon]]-13 (but not carbon-12!) possess an intrinsic degree of freedom called nuclear angular momentum or [[nuclear spin/Definition|Spin]]. When atoms are exposed to an external [[magnetic field]], the spins align themselves with the direction of the magnetic field and precess in relation to the field. Applying a radio-frequency pulse perpendicular to this field causes them to move in phase. | |||
The tissue relaxes after the external radio-pulse is turned off.<ref name="PMID6506686"/> Different tissues have different relaxation times. These relaxation time differences can be used to generate image contrast. | |||
In the absence of an external magnetic field, the individual nuclear magnetic fields point in random directions, resulting in no net magnetic field. However, in the presence of an external magnetic field, a fraction of the atoms align with the magnetic field while others align against the external field, resulting in a net magnetic field (the macroscopic measure of many spins) that can be measured. The observed signal is the small net magnetic field resulting from the population differences between the "up" and "down" nuclei. Because the population difference between the atoms aligned with or against the field is a function of the external magnetic field strength, increasing the magnetic field strength of MRI spectrometers enhances the observed signal-to-noise ratio. | |||
For clinical applications, MRI units range in field strengths from 0.05 T to 3.0 Tesla.<ref> Dominik Weishaupt, How Does Mri Work? An Introduction to the Physics And Function of Magnetic resonance imaging Springer, 2006 </ref> | |||
{| class="wikitable" | |||
|+ MRI pulse sequences | |+ MRI pulse sequences | ||
! Pulse sequence !! Description !!Application | ! Pulse sequence !! Description !!Application | ||
| Line 19: | Line 29: | ||
| colspan=3 align="center" |'''Standard pulse sequences''' | | colspan=3 align="center" |'''Standard pulse sequences''' | ||
|- | |- | ||
| Spin | | Spin echo || Proton density (water)|| thoracic imaging | ||
|- | |- | ||
| T1 relaxation time || Spin-lattice (longitudinal) relaxation time. Short TR & TE|| More solid and less mobile molecules (including [[lipid]]s, cerebral white matter, yellow bone marrow) are bright.<br>T1 images can be obtained faster.<br>T1 images better display [[gadolinium]] [[contrast medium]]<ref name="PMID8433731"/> | | T1 relaxation time || Spin-lattice (longitudinal) relaxation time. Short repetition time (TR) & echo time (TE)|| More solid and less mobile molecules (including [[lipid]]s, cerebral white matter, yellow bone marrow) are bright.<br>T1 images can be obtained faster.<br>T1 images better display [[gadolinium]] [[contrast medium]]<ref name="PMID8433731"/> | ||
|- | |- | ||
| T2 relaxation time || Spin-spin (transverse) relaxation time. Long TR & TE|| Water (including [[cerebrospinal fluid|CSF]], [[urine]], cysts, [[abscess]]es) is bright<ref name="PMID8433731"/> | | T2 relaxation time || Spin-spin (transverse) relaxation time. Long TR & TE|| Water (including [[cerebrospinal fluid|CSF]], [[urine]], cysts, [[abscess]]es) is bright<ref name="PMID8433731"/> | ||
| Line 27: | Line 37: | ||
| colspan=3 align="center" |'''Other pulse sequences''' | | colspan=3 align="center" |'''Other pulse sequences''' | ||
|- | |- | ||
| DWI (diffusion-weighted imaging)|| || | | DWI ([[Diffusion magnetic resonance imaging|diffusion-weighted imaging]])|| || [[Brain ischemia]]<br/>Tumor response to treatment | ||
|- | |- | ||
| ADC (apparent diffusion coefficient) || || | | ADC (apparent diffusion coefficient) || || | ||
| Line 35: | Line 45: | ||
| PWI (perfusion-weighted imaging) || || | | PWI (perfusion-weighted imaging) || || | ||
|} | |} | ||
<br /> | |||
==Interpretation== | |||
The accuracy of interpretation depends on the quality of both the MRI machine used and the quality of the radiologist.<ref name="urlThe Scan That Didn’t Scan - NYTimes.com">{{cite web |url=http://www.nytimes.com/2008/10/14/health/14scan.html |title=The Scan That Didn’t Scan - NYTimes.com |author= |authorlink= |coauthors= |date= |format= |work= |publisher= |pages= |language= |archiveurl= |archivedate= |quote= |accessdate=}}</ref> | |||
== Therapeutic Application== | |||
The principle of magnetic resonance is also used therapeutically. It is referred to as Magnetic Resonance Therapy. Supporters of the therapy claim a broad indication spectrum in nonconservative orthopedics. <ref> Salomonowitz G. et al. (2011) Impact of magnetic resonance therapy on sickness absence of patients with nerve root irritation following a lumbar disc problem, Z Orthop Unfall, Oct; 149(5):575-81. PMID: 21984428 </ref> | |||
<ref> A. Levers, M. Staat, W. van Laack (2011), Analysis of the Long-term Effect of the Nuclear Magnetic Resonance Therapy on Gonarthrosis, Special edition from Orthopedic Practice 11/2011 </ref> | |||
==Adverse effects== | |||
===[[Claustrophobia]]=== | |||
===Nephrogenic systemic dermopathy=== | |||
The use of [[gadolinium]]-based [[contrast agent]]s in patients with [[renal insufficiency]] may increase the risk of [[nephrogenic systemic dermopathy]] (nephrogenic systemic fibrosis).<ref name="pmid19841395">{{cite journal| author=Lee CU, Wood CM, Hesley GK, Leung N, Bridges MD, Lund JT et al.| title=Large sample of nephrogenic systemic fibrosis cases from a single institution. | journal=Arch Dermatol | year= 2009 | volume= 145 | issue= 10 | pages= 1095-102 | pmid=19841395 | |||
| url=http://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&retmode=ref&cmd=prlinks&id=19841395 | doi=10.1001/archdermatol.2009.232 }} <!--Formatted by http://sumsearch.uthscsa.edu/cite/--></ref><ref name="pmid19709997">{{cite journal| author=Abujudeh HH, Kaewlai R, Kagan A, Chibnik LB, Nazarian RM, High WA et al.| title=Nephrogenic systemic fibrosis after gadopentetate dimeglumine exposure: case series of 36 patients. | journal=Radiology | year= 2009 | volume= 253 | issue= 1 | pages= 81-9 | pmid=19709997 | |||
| url=http://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&retmode=ref&cmd=prlinks&id=19709997 | doi=10.1148/radiol.2531082160 }} <!--Formatted by http://sumsearch.uthscsa.edu/cite/--></ref> Among patients on [[hemodialysis]], the risk may be 1% after use of [[gadolinium]]-based [[contrast agent]]s.<ref name="pmid19841395"/> | |||
In the [[United States of America]], the [[Food and Drug Administration]] cautions against using [[gadolinium]]-based [[contrast agent]]s if:<ref>Anonymous (5/23/2007) [http://www.fda.gov/Safety/MedWatch/SafetyInformation/SafetyAlertsforHumanMedicalProducts/ucm152672.htm Information for Healthcare Professionals Gadolinium-Based Contrast Agents for Magnetic resonance imaging (marketed as Magnevist, MultiHance, Omniscan, OptiMARK, ProHance)]. Food and Drug Administration</ref> | |||
* [[Glomerular filtration rate]] is less than 30 mL/min/1.73m<sup>2</sup> | |||
* [[Hepatorenal syndrome]] or peri-operative liver transplantation period | |||
==References== | ==References== | ||
{{reflist|2}} | |||
Latest revision as of 04:54, 21 March 2024
Magnetic resonance imaging (also known as Nuclear Magnetic Resonance imaging or as an MRI scan) is a non-destructive imaging technique with a wide range of applications in the materials sciences and life sciences, including diagnostic imaging and neuroimaging. It employs the principle of nuclear magnetic resonance and is thus, in essence, a variant of NMR spectroscopy in which the focus is on providing information regarding the distribution of nuclei in space. The information regarding the spatial distribution of nuclei is usually provided in the form of a plot showing the variation of the density (number of nuclei of interest per unit volume) as a function of the position. In the case of medical MRI, the most commonly used nucleus is the nucleus of the hydrogen atom. Most biomedical MR images are essentially plots showing the distribution of water in the body because water constitutes about 70% of the total body weight of human beings. The technology developed as a result of research on the effect of gravity on light by Robert Pound.
Classification
- Echo-planar imaging allows much faster acquisition of images.
- Functional magnetic resonance imaging uses echo-planar imaging and measures changes in oxygenation status of hemoglobin in response to specific sensory or motor stimulation.[1][2][3]
- Magnetic resonance angiography (perfusion-weighted imaging)
- NMR spectroscopy[4]
- Magnetic resonance microscopy - concerned with imaging at resolutions around or below the resolution limit if the human eye (about 100µm)
- Localized spectroscopy - combines MR spectroscopy and MR imaging by providing spectroscopic information from specific spatial locations within the sample
- Chemical-shift imaging - combines NMR spectroscopy and MR imaging by providing information about the variation in the spatial distribution of nuclei having spectroscopically distinguishable values of chemical shifts
- Cine magnetic resonance imaging is primarily used in cardiology.
- Diffusion magnetic resonance imaging (diffusion-weighted imaging) usually uses echo-planar imaging and measures changes in the apparent diffusion coefficient (ADC).
Physical principles
In contrast to x-ray computed tomography which is based on the density of electrons in tissues, MRI is based on several properties of protons.[5][6][7][8][9]
Atoms with an odd number of nucleons (protons and neutrons), such as hydrogen and carbon-13 (but not carbon-12!) possess an intrinsic degree of freedom called nuclear angular momentum or Spin. When atoms are exposed to an external magnetic field, the spins align themselves with the direction of the magnetic field and precess in relation to the field. Applying a radio-frequency pulse perpendicular to this field causes them to move in phase. The tissue relaxes after the external radio-pulse is turned off.[5] Different tissues have different relaxation times. These relaxation time differences can be used to generate image contrast. In the absence of an external magnetic field, the individual nuclear magnetic fields point in random directions, resulting in no net magnetic field. However, in the presence of an external magnetic field, a fraction of the atoms align with the magnetic field while others align against the external field, resulting in a net magnetic field (the macroscopic measure of many spins) that can be measured. The observed signal is the small net magnetic field resulting from the population differences between the "up" and "down" nuclei. Because the population difference between the atoms aligned with or against the field is a function of the external magnetic field strength, increasing the magnetic field strength of MRI spectrometers enhances the observed signal-to-noise ratio.
For clinical applications, MRI units range in field strengths from 0.05 T to 3.0 Tesla.[10]
| Pulse sequence | Description | Application |
|---|---|---|
| Standard pulse sequences | ||
| Spin echo | Proton density (water) | thoracic imaging |
| T1 relaxation time | Spin-lattice (longitudinal) relaxation time. Short repetition time (TR) & echo time (TE) | More solid and less mobile molecules (including lipids, cerebral white matter, yellow bone marrow) are bright. T1 images can be obtained faster. T1 images better display gadolinium contrast medium[7] |
| T2 relaxation time | Spin-spin (transverse) relaxation time. Long TR & TE | Water (including CSF, urine, cysts, abscesses) is bright[7] |
| Other pulse sequences | ||
| DWI (diffusion-weighted imaging) | Brain ischemia Tumor response to treatment | |
| ADC (apparent diffusion coefficient) | ||
| GRE (gradient echo) pulse sequences | Blood flow is bright | |
| PWI (perfusion-weighted imaging) | ||
Interpretation
The accuracy of interpretation depends on the quality of both the MRI machine used and the quality of the radiologist.[11]
Therapeutic Application
The principle of magnetic resonance is also used therapeutically. It is referred to as Magnetic Resonance Therapy. Supporters of the therapy claim a broad indication spectrum in nonconservative orthopedics. [12] [13]
Adverse effects
Claustrophobia
Nephrogenic systemic dermopathy
The use of gadolinium-based contrast agents in patients with renal insufficiency may increase the risk of nephrogenic systemic dermopathy (nephrogenic systemic fibrosis).[14][15] Among patients on hemodialysis, the risk may be 1% after use of gadolinium-based contrast agents.[14]
In the United States of America, the Food and Drug Administration cautions against using gadolinium-based contrast agents if:[16]
- Glomerular filtration rate is less than 30 mL/min/1.73m2
- Hepatorenal syndrome or peri-operative liver transplantation period
References
- ↑ Le Bihan D, Jezzard P, Haxby J, Sadato N, Rueckert L, Mattay V. Functional magnetic resonance imaging of the brain. Ann Intern Med. 1995 Feb 15;122(4):296-303. PMID 7825767
- ↑ Gilman S. Imaging the brain. First of two parts. N Engl J Med. 1998 Mar 19;338(12):812-20. PMID 9504943
- ↑ Gilman S. Imaging the brain. Second of two parts. N Engl J Med. 1998 Mar 26;338(13):889-96. PMID 9516225
- ↑ Fisher M, Prichard JW, Warach S. New magnetic resonance techniques for acute ischemic stroke. JAMA. 1995 Sep 20;274(11):908-11. PMID 7674506
- ↑ 5.0 5.1 Hendee WR, Morgan CJ. Magnetic resonance imaging. Part I--physical principles. West J Med. 1984 Oct;141(4):491-500. PMID 6506686
- ↑ Hendee WR, Morgan CJ. Magnetic resonance imaging. Part II--Clinical applications. West J Med. 1984 Nov;141(5):638-48. PMID 6516335
- ↑ 7.0 7.1 7.2 Edelman RR, Warach S. Magnetic resonance imaging - First of Two Parts. N Engl J Med. 1993 Mar 11;328(10):708-16. PMID 8433731
- ↑ Edelman RR, Warach S. Magnetic resonance imaging - Second of Two Parts. N Engl J Med. 1993 Mar 18;328(11):785-91. PMID 8369029
- ↑ Berger A. Magnetic resonance imaging. BMJ. 2002 Jan 5;324(7328):35. PMID 11777806
- ↑ Dominik Weishaupt, How Does Mri Work? An Introduction to the Physics And Function of Magnetic resonance imaging Springer, 2006
- ↑ The Scan That Didn’t Scan - NYTimes.com.
- ↑ Salomonowitz G. et al. (2011) Impact of magnetic resonance therapy on sickness absence of patients with nerve root irritation following a lumbar disc problem, Z Orthop Unfall, Oct; 149(5):575-81. PMID: 21984428
- ↑ A. Levers, M. Staat, W. van Laack (2011), Analysis of the Long-term Effect of the Nuclear Magnetic Resonance Therapy on Gonarthrosis, Special edition from Orthopedic Practice 11/2011
- ↑ 14.0 14.1 Lee CU, Wood CM, Hesley GK, Leung N, Bridges MD, Lund JT et al. (2009). "Large sample of nephrogenic systemic fibrosis cases from a single institution.". Arch Dermatol 145 (10): 1095-102. DOI:10.1001/archdermatol.2009.232. PMID 19841395. Research Blogging.
- ↑ Abujudeh HH, Kaewlai R, Kagan A, Chibnik LB, Nazarian RM, High WA et al. (2009). "Nephrogenic systemic fibrosis after gadopentetate dimeglumine exposure: case series of 36 patients.". Radiology 253 (1): 81-9. DOI:10.1148/radiol.2531082160. PMID 19709997. Research Blogging.
- ↑ Anonymous (5/23/2007) Information for Healthcare Professionals Gadolinium-Based Contrast Agents for Magnetic resonance imaging (marketed as Magnevist, MultiHance, Omniscan, OptiMARK, ProHance). Food and Drug Administration