[Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]

C Arndt; J Graessner; M C Cramer; K Petersen; Fabian Reitmeier; F Weiss; Michael Kaul; Michael Jaehne; G Adam; C R Habermann

[Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]

Standard

[Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]. / Arndt, C; Graessner, J; Cramer, M C; Petersen, K; Reitmeier, Fabian; Weiss, F; Kaul, Michael; Jaehne, Michael; Adam, G; Habermann, C R.

In: ROFO-FORTSCHR RONTG, Vol. 178, No. 9, 9, 2006, p. 893-897.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Arndt, C, Graessner, J, Cramer, MC, Petersen, K, Reitmeier, F, Weiss, F, Kaul, M, Jaehne, M, Adam, G & Habermann, CR 2006, '[Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]', ROFO-FORTSCHR RONTG, vol. 178, no. 9, 9, pp. 893-897. <http://www.ncbi.nlm.nih.gov/pubmed/16953481?dopt=Citation>

APA

Arndt, C., Graessner, J., Cramer, M. C., Petersen, K., Reitmeier, F., Weiss, F., Kaul, M., Jaehne, M., Adam, G., & Habermann, C. R. (2006). [Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]. ROFO-FORTSCHR RONTG, 178(9), 893-897. [9]. http://www.ncbi.nlm.nih.gov/pubmed/16953481?dopt=Citation

Vancouver

Arndt C, Graessner J, Cramer MC, Petersen K, Reitmeier F, Weiss F et al. [Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]. ROFO-FORTSCHR RONTG. 2006;178(9):893-897. 9.

Bibtex

@article{5fd18bb5cba0436bb097f88ab87cd94f,

title = "[Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]",

abstract = "PURPOSE: To investigate the feasibility of diffusion-weighted (DWI) echo-planar imaging (EPI) to depict the submandibular glands and to measure different functional conditions. MATERIALS AND METHODS: Twenty-seven healthy volunteers were examined. Diffusion weighted sequence was performed prior to stimulation. Exactly 30 seconds after a commercially available lemon juice was given orally, the diffusion weighted sequence was repeated. All examinations were performed by using a 1.5-T superconducting system with a 30 mT/m maximum gradient capability and maximum slew rate of 125 mT/m/sec (Magnetom Symphony, Siemens, Erlangen, Germany). The lower part of the circularly polarized (CP) head coil and a standard two-element CP neck array coil were used. The flexibility of the neck array coil allowed positioning the N1 element (upper part of the coil) right next to the submandibular gland. The axial diffusion-weighted EPI (echo planar imaging) sequence was performed using a matrix of 119 x 128, a field of view of 250 x 250 mm (pixel size 2.1 x 1.95 mm), a section thickness of 5 mm with an interslice gap of 1 mm. The b factors used were 0 sec/mm(2), 500 sec/ mm(2) and 1000 sec/mm(2). Apparent diffusion coefficiant (ADC) maps were digitally transferred to MRIcro (Chris Rorden, Universitiy of Nottingham, Great Britain). After detecting the submandibular glands a region of interest (ROI) was placed manually exactly within the boarder of both submandibular glands, excluding the external carotid artery on ADC maps. These procedures were performed on all ADC slices the submandibular glands could be differentiated in before and after oral stimulation. For statistical comparison of results, a student's t-test was performed with an overall two-tailed significance level of p = 0.05. RESULTS: The visualization of the submandibular glands using the diffusion-weighted EPI sequence was possible in all of the 27 volunteers. Prior to oral stimulation an ADC of 1.31 x 10(-3) mm(2)/sec (95 % CI, 1.39 x 10(-3) mm(2)/sec, 1.44 x 10(-3) mm(2)/sec) was calculated which increased to 1.41 x 10(-3) mm(2)/sec (95 % KI, 1.39 x 10(- 3) mm(2)/sec, 1.44 x 10(-3) mm(2)/sec) 30 seconds after stimulation. This increase proved to be significant (p <0.001). CONCLUSION: Diffusion-weighted echo-planar MR imaging allows non-invasive quantification of functional changes in the submandibular gland.",

author = "C Arndt and J Graessner and Cramer, {M C} and K Petersen and Fabian Reitmeier and F Weiss and Michael Kaul and Michael Jaehne and G Adam and Habermann, {C R}",

year = "2006",

language = "Deutsch",

volume = "178",

pages = "893--897",

journal = "ROFO-FORTSCHR RONTG",

issn = "1438-9029",

publisher = "Georg Thieme Verlag KG",

number = "9",

}

RIS

TY - JOUR

T1 - [Functional imaging of submandibular glands: diffusion-weighted echo-planar MRI before and after stimulation]

AU - Arndt, C

AU - Graessner, J

AU - Cramer, M C

AU - Petersen, K

AU - Reitmeier, Fabian

AU - Weiss, F

AU - Kaul, Michael

AU - Jaehne, Michael

AU - Adam, G

AU - Habermann, C R

PY - 2006

Y1 - 2006

N2 - PURPOSE: To investigate the feasibility of diffusion-weighted (DWI) echo-planar imaging (EPI) to depict the submandibular glands and to measure different functional conditions. MATERIALS AND METHODS: Twenty-seven healthy volunteers were examined. Diffusion weighted sequence was performed prior to stimulation. Exactly 30 seconds after a commercially available lemon juice was given orally, the diffusion weighted sequence was repeated. All examinations were performed by using a 1.5-T superconducting system with a 30 mT/m maximum gradient capability and maximum slew rate of 125 mT/m/sec (Magnetom Symphony, Siemens, Erlangen, Germany). The lower part of the circularly polarized (CP) head coil and a standard two-element CP neck array coil were used. The flexibility of the neck array coil allowed positioning the N1 element (upper part of the coil) right next to the submandibular gland. The axial diffusion-weighted EPI (echo planar imaging) sequence was performed using a matrix of 119 x 128, a field of view of 250 x 250 mm (pixel size 2.1 x 1.95 mm), a section thickness of 5 mm with an interslice gap of 1 mm. The b factors used were 0 sec/mm(2), 500 sec/ mm(2) and 1000 sec/mm(2). Apparent diffusion coefficiant (ADC) maps were digitally transferred to MRIcro (Chris Rorden, Universitiy of Nottingham, Great Britain). After detecting the submandibular glands a region of interest (ROI) was placed manually exactly within the boarder of both submandibular glands, excluding the external carotid artery on ADC maps. These procedures were performed on all ADC slices the submandibular glands could be differentiated in before and after oral stimulation. For statistical comparison of results, a student's t-test was performed with an overall two-tailed significance level of p = 0.05. RESULTS: The visualization of the submandibular glands using the diffusion-weighted EPI sequence was possible in all of the 27 volunteers. Prior to oral stimulation an ADC of 1.31 x 10(-3) mm(2)/sec (95 % CI, 1.39 x 10(-3) mm(2)/sec, 1.44 x 10(-3) mm(2)/sec) was calculated which increased to 1.41 x 10(-3) mm(2)/sec (95 % KI, 1.39 x 10(- 3) mm(2)/sec, 1.44 x 10(-3) mm(2)/sec) 30 seconds after stimulation. This increase proved to be significant (p <0.001). CONCLUSION: Diffusion-weighted echo-planar MR imaging allows non-invasive quantification of functional changes in the submandibular gland.

AB - PURPOSE: To investigate the feasibility of diffusion-weighted (DWI) echo-planar imaging (EPI) to depict the submandibular glands and to measure different functional conditions. MATERIALS AND METHODS: Twenty-seven healthy volunteers were examined. Diffusion weighted sequence was performed prior to stimulation. Exactly 30 seconds after a commercially available lemon juice was given orally, the diffusion weighted sequence was repeated. All examinations were performed by using a 1.5-T superconducting system with a 30 mT/m maximum gradient capability and maximum slew rate of 125 mT/m/sec (Magnetom Symphony, Siemens, Erlangen, Germany). The lower part of the circularly polarized (CP) head coil and a standard two-element CP neck array coil were used. The flexibility of the neck array coil allowed positioning the N1 element (upper part of the coil) right next to the submandibular gland. The axial diffusion-weighted EPI (echo planar imaging) sequence was performed using a matrix of 119 x 128, a field of view of 250 x 250 mm (pixel size 2.1 x 1.95 mm), a section thickness of 5 mm with an interslice gap of 1 mm. The b factors used were 0 sec/mm(2), 500 sec/ mm(2) and 1000 sec/mm(2). Apparent diffusion coefficiant (ADC) maps were digitally transferred to MRIcro (Chris Rorden, Universitiy of Nottingham, Great Britain). After detecting the submandibular glands a region of interest (ROI) was placed manually exactly within the boarder of both submandibular glands, excluding the external carotid artery on ADC maps. These procedures were performed on all ADC slices the submandibular glands could be differentiated in before and after oral stimulation. For statistical comparison of results, a student's t-test was performed with an overall two-tailed significance level of p = 0.05. RESULTS: The visualization of the submandibular glands using the diffusion-weighted EPI sequence was possible in all of the 27 volunteers. Prior to oral stimulation an ADC of 1.31 x 10(-3) mm(2)/sec (95 % CI, 1.39 x 10(-3) mm(2)/sec, 1.44 x 10(-3) mm(2)/sec) was calculated which increased to 1.41 x 10(-3) mm(2)/sec (95 % KI, 1.39 x 10(- 3) mm(2)/sec, 1.44 x 10(-3) mm(2)/sec) 30 seconds after stimulation. This increase proved to be significant (p <0.001). CONCLUSION: Diffusion-weighted echo-planar MR imaging allows non-invasive quantification of functional changes in the submandibular gland.

M3 - SCORING: Zeitschriftenaufsatz

VL - 178

SP - 893

EP - 897

JO - ROFO-FORTSCHR RONTG

JF - ROFO-FORTSCHR RONTG

SN - 1438-9029

IS - 9

M1 - 9

ER -