Investigation of an implantable dosimeter for single-point water equivalent path length verification in proton therapy
Purpose: In vivo range verification in proton therapy is highly desirable. A recent study suggested that it was feasible to use point dose measurement for in vivo beam range verification in proton therapy, provided that the spread-out Bragg peak dose distribution is delivered in a different and rath...
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| Veröffentlicht in: | Medical physics (Lancaster) 2010-11, Vol.37 (11), p.5858-5866 |
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| creator | Lu, Hsiao-Ming Mann, Greg Cascio, Ethan |
| description | Purpose:
In vivo range verification in proton therapy is highly desirable. A recent study suggested that it was feasible to use point dose measurement for in vivo beam range verification in proton therapy, provided that the spread-out Bragg peak dose distribution is delivered in a different and rather unconventional manner. In this work, the authors investigate the possibility of using a commercial implantable dosimeter with wireless reading for this particular application.
Methods:
The traditional proton treatment technique delivers all the Bragg peaks required for a SOBP field in a single sequence, producing a constant dose plateau across the target volume. As a result, a point dose measurement anywhere in the target volume will produce the same value, thus providing no information regarding the water equivalent path length to the point of measurement. However, the same constant dose distribution can be achieved by splitting the field into a complementary pair of subfields, producing two oppositely “sloped” depth-dose distributions, respectively. The ratio between the two distributions can be a sensitive function of depth and measuring this ratio at a point inside the target volume can provide the water equivalent path length to the dosimeter location. Two types of field splits were used in the experiment, one achieved by the technique of beam current modulation and the other by manipulating the location and width of the beam pulse relative to the range modulator track. Eight MOSFET-based implantable dosimeters at four different depths in a water tank were used to measure the dose ratios for these field pairs. A method was developed to correct the effect of the well-known LET dependence of the MOSFET detectors on the depth-dose distributions using the columnar recombination model. The LET-corrected dose ratios were used to derive the water equivalent path lengths to the dosimeter locations to be compared to physical measurements.
Results:
The implantable dosimeters measured the dose ratios with a reasonable relative uncertainty of 1%–3% at all depths, except when the ratio itself becomes very small. In total, 55% of the individual measurements reproduced the water equivalent path lengths to the dosimeters within 1 mm. For three dosimeters, the difference was consistently less than 1 mm. Half of the standard deviations over the repeated measurements were equal or less than 1 mm.
Conclusions:
With a single fitting parameter, the LET-correction method worke |
| doi_str_mv | 10.1118/1.3504609 |
| format | Article |
| fullrecord | <record><control><sourceid>proquest_osti_</sourceid><recordid>TN_cdi_osti_scitechconnect_22096818</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><sourcerecordid>818641065</sourcerecordid><originalsourceid>FETCH-LOGICAL-c6309-c8248da0b561ae6cc13f0bb2389918a10752f391a5ab3644aeb37230d8f2e7e83</originalsourceid><addsrcrecordid>eNp9kk1v1DAQhi0EotvCgT-AInFAVErxV7LOASRUFajUCg5wthxnvGuU2KntTbX_Hi_ZVq3Q9jTW-Jl3xu8YoTcEnxFCxEdyxirMa9w8QwvKl6zkFDfP0QLjhpeU4-oIHcf4B2NcZ_AlOqKEVII2YoGmSzdBTHalkvWu8KZQrrDD2CuXVNtD0floB0gQCuNDEa1b9VCO3rpU3KpdGm42dlI95MSo0rrIp1UOEwRrrJ5lrSvG4FM-pTUENW5foRdG9RFe7-MJ-v314tf59_Lqx7fL8y9Xpa4ZbkotKBedwm1VEwW11oQZ3LaUiaYhQhG8rKhhDVGValnNuYKWLSnDnTAUliDYCfo8646bdoBO5ymD6uUY7KDCVnpl5eMbZ9dy5SeZzcEV51ng3Szgs0kyaptAr7V3DnSSNNtcC7Jr837fJvibTfZTDjZq6LOL4DdRZqbmBNdVJj_MpA4-xgDmfhaC5W6Zksj9MjP79uHw9-Td9jJQzsCt7WF7WEle_9wLfpr53Tv-beZwzaN_Ib2RyuX600P1kw8P-o2deQr-_6l_ARxT21U</addsrcrecordid><sourcetype>Open Access Repository</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype><pqid>818641065</pqid></control><display><type>article</type><title>Investigation of an implantable dosimeter for single-point water equivalent path length verification in proton therapy</title><source>MEDLINE</source><source>Wiley Online Library Journals Frontfile Complete</source><source>Alma/SFX Local Collection</source><creator>Lu, Hsiao-Ming ; Mann, Greg ; Cascio, Ethan</creator><creatorcontrib>Lu, Hsiao-Ming ; Mann, Greg ; Cascio, Ethan</creatorcontrib><description>Purpose:
In vivo range verification in proton therapy is highly desirable. A recent study suggested that it was feasible to use point dose measurement for in vivo beam range verification in proton therapy, provided that the spread-out Bragg peak dose distribution is delivered in a different and rather unconventional manner. In this work, the authors investigate the possibility of using a commercial implantable dosimeter with wireless reading for this particular application.
Methods:
The traditional proton treatment technique delivers all the Bragg peaks required for a SOBP field in a single sequence, producing a constant dose plateau across the target volume. As a result, a point dose measurement anywhere in the target volume will produce the same value, thus providing no information regarding the water equivalent path length to the point of measurement. However, the same constant dose distribution can be achieved by splitting the field into a complementary pair of subfields, producing two oppositely “sloped” depth-dose distributions, respectively. The ratio between the two distributions can be a sensitive function of depth and measuring this ratio at a point inside the target volume can provide the water equivalent path length to the dosimeter location. Two types of field splits were used in the experiment, one achieved by the technique of beam current modulation and the other by manipulating the location and width of the beam pulse relative to the range modulator track. Eight MOSFET-based implantable dosimeters at four different depths in a water tank were used to measure the dose ratios for these field pairs. A method was developed to correct the effect of the well-known LET dependence of the MOSFET detectors on the depth-dose distributions using the columnar recombination model. The LET-corrected dose ratios were used to derive the water equivalent path lengths to the dosimeter locations to be compared to physical measurements.
Results:
The implantable dosimeters measured the dose ratios with a reasonable relative uncertainty of 1%–3% at all depths, except when the ratio itself becomes very small. In total, 55% of the individual measurements reproduced the water equivalent path lengths to the dosimeters within 1 mm. For three dosimeters, the difference was consistently less than 1 mm. Half of the standard deviations over the repeated measurements were equal or less than 1 mm.
Conclusions:
With a single fitting parameter, the LET-correction method worked remarkably well for the MOSFET detectors. The overall results were very encouraging for a potential method ofin vivo beam range verification with millimeter accuracy. This is sufficient accuracy to expand range of clinical applications in which the authors could use the distal fall off of the proton depth dose for tight margins.</description><identifier>ISSN: 0094-2405</identifier><identifier>EISSN: 2473-4209</identifier><identifier>EISSN: 0094-2405</identifier><identifier>DOI: 10.1118/1.3504609</identifier><identifier>PMID: 21158298</identifier><identifier>CODEN: MPHYA6</identifier><language>eng</language><publisher>United States: American Association of Physicists in Medicine</publisher><subject>60 APPLIED LIFE SCIENCES ; ACCURACY ; Algorithms ; BEAM CURRENTS ; BEAM PULSERS ; BEAMS ; Biomedical engineering ; BRAGG CURVE ; Collisional energy loss ; DEPTH DOSE DISTRIBUTIONS ; DOSEMETERS ; Dose‐volume analysis ; dosimeters ; DOSIMETRY ; Dosimetry/exposure assessment ; Electric fields ; Electric measurements ; Humans ; IN VIVO ; in vivo dosimetry ; INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY ; Ionization chambers ; LET dependence ; Models, Statistical ; Modulators ; MOSFET ; MOSFETs ; particle detectors ; particle therapy ; prosthetics ; Proton therapy ; PROTONS ; Protons - therapeutic use ; Radiation detectors ; Radiation Dosage ; RADIATION DOSES ; RADIATION PROTECTION AND DOSIMETRY ; radiation therapy ; Radiation Therapy Physics ; RADIOLOGY AND NUCLEAR MEDICINE ; Radiometry - instrumentation ; Radiometry - methods ; RADIOTHERAPY ; Radiotherapy Dosage ; range uncertainty ; Reproducibility of Results ; SENSORS ; Therapeutic applications, including brachytherapy ; Time Factors ; VERIFICATION ; WATER ; Water - chemistry</subject><ispartof>Medical physics (Lancaster), 2010-11, Vol.37 (11), p.5858-5866</ispartof><rights>American Association of Physicists in Medicine</rights><rights>2010 American Association of Physicists in Medicine</rights><rights>Copyright © 2010 American Association of Physicists in Medicine 2010 American Association of Physicists in Medicine</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c6309-c8248da0b561ae6cc13f0bb2389918a10752f391a5ab3644aeb37230d8f2e7e83</citedby><cites>FETCH-LOGICAL-c6309-c8248da0b561ae6cc13f0bb2389918a10752f391a5ab3644aeb37230d8f2e7e83</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://onlinelibrary.wiley.com/doi/pdf/10.1118%2F1.3504609$$EPDF$$P50$$Gwiley$$H</linktopdf><linktohtml>$$Uhttps://onlinelibrary.wiley.com/doi/full/10.1118%2F1.3504609$$EHTML$$P50$$Gwiley$$H</linktohtml><link.rule.ids>230,314,776,780,881,1411,27901,27902,45550,45551</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/21158298$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink><backlink>$$Uhttps://www.osti.gov/biblio/22096818$$D View this record in Osti.gov$$Hfree_for_read</backlink></links><search><creatorcontrib>Lu, Hsiao-Ming</creatorcontrib><creatorcontrib>Mann, Greg</creatorcontrib><creatorcontrib>Cascio, Ethan</creatorcontrib><title>Investigation of an implantable dosimeter for single-point water equivalent path length verification in proton therapy</title><title>Medical physics (Lancaster)</title><addtitle>Med Phys</addtitle><description>Purpose:
In vivo range verification in proton therapy is highly desirable. A recent study suggested that it was feasible to use point dose measurement for in vivo beam range verification in proton therapy, provided that the spread-out Bragg peak dose distribution is delivered in a different and rather unconventional manner. In this work, the authors investigate the possibility of using a commercial implantable dosimeter with wireless reading for this particular application.
Methods:
The traditional proton treatment technique delivers all the Bragg peaks required for a SOBP field in a single sequence, producing a constant dose plateau across the target volume. As a result, a point dose measurement anywhere in the target volume will produce the same value, thus providing no information regarding the water equivalent path length to the point of measurement. However, the same constant dose distribution can be achieved by splitting the field into a complementary pair of subfields, producing two oppositely “sloped” depth-dose distributions, respectively. The ratio between the two distributions can be a sensitive function of depth and measuring this ratio at a point inside the target volume can provide the water equivalent path length to the dosimeter location. Two types of field splits were used in the experiment, one achieved by the technique of beam current modulation and the other by manipulating the location and width of the beam pulse relative to the range modulator track. Eight MOSFET-based implantable dosimeters at four different depths in a water tank were used to measure the dose ratios for these field pairs. A method was developed to correct the effect of the well-known LET dependence of the MOSFET detectors on the depth-dose distributions using the columnar recombination model. The LET-corrected dose ratios were used to derive the water equivalent path lengths to the dosimeter locations to be compared to physical measurements.
Results:
The implantable dosimeters measured the dose ratios with a reasonable relative uncertainty of 1%–3% at all depths, except when the ratio itself becomes very small. In total, 55% of the individual measurements reproduced the water equivalent path lengths to the dosimeters within 1 mm. For three dosimeters, the difference was consistently less than 1 mm. Half of the standard deviations over the repeated measurements were equal or less than 1 mm.
Conclusions:
With a single fitting parameter, the LET-correction method worked remarkably well for the MOSFET detectors. The overall results were very encouraging for a potential method ofin vivo beam range verification with millimeter accuracy. This is sufficient accuracy to expand range of clinical applications in which the authors could use the distal fall off of the proton depth dose for tight margins.</description><subject>60 APPLIED LIFE SCIENCES</subject><subject>ACCURACY</subject><subject>Algorithms</subject><subject>BEAM CURRENTS</subject><subject>BEAM PULSERS</subject><subject>BEAMS</subject><subject>Biomedical engineering</subject><subject>BRAGG CURVE</subject><subject>Collisional energy loss</subject><subject>DEPTH DOSE DISTRIBUTIONS</subject><subject>DOSEMETERS</subject><subject>Dose‐volume analysis</subject><subject>dosimeters</subject><subject>DOSIMETRY</subject><subject>Dosimetry/exposure assessment</subject><subject>Electric fields</subject><subject>Electric measurements</subject><subject>Humans</subject><subject>IN VIVO</subject><subject>in vivo dosimetry</subject><subject>INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY</subject><subject>Ionization chambers</subject><subject>LET dependence</subject><subject>Models, Statistical</subject><subject>Modulators</subject><subject>MOSFET</subject><subject>MOSFETs</subject><subject>particle detectors</subject><subject>particle therapy</subject><subject>prosthetics</subject><subject>Proton therapy</subject><subject>PROTONS</subject><subject>Protons - therapeutic use</subject><subject>Radiation detectors</subject><subject>Radiation Dosage</subject><subject>RADIATION DOSES</subject><subject>RADIATION PROTECTION AND DOSIMETRY</subject><subject>radiation therapy</subject><subject>Radiation Therapy Physics</subject><subject>RADIOLOGY AND NUCLEAR MEDICINE</subject><subject>Radiometry - instrumentation</subject><subject>Radiometry - methods</subject><subject>RADIOTHERAPY</subject><subject>Radiotherapy Dosage</subject><subject>range uncertainty</subject><subject>Reproducibility of Results</subject><subject>SENSORS</subject><subject>Therapeutic applications, including brachytherapy</subject><subject>Time Factors</subject><subject>VERIFICATION</subject><subject>WATER</subject><subject>Water - chemistry</subject><issn>0094-2405</issn><issn>2473-4209</issn><issn>0094-2405</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2010</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNp9kk1v1DAQhi0EotvCgT-AInFAVErxV7LOASRUFajUCg5wthxnvGuU2KntTbX_Hi_ZVq3Q9jTW-Jl3xu8YoTcEnxFCxEdyxirMa9w8QwvKl6zkFDfP0QLjhpeU4-oIHcf4B2NcZ_AlOqKEVII2YoGmSzdBTHalkvWu8KZQrrDD2CuXVNtD0floB0gQCuNDEa1b9VCO3rpU3KpdGm42dlI95MSo0rrIp1UOEwRrrJ5lrSvG4FM-pTUENW5foRdG9RFe7-MJ-v314tf59_Lqx7fL8y9Xpa4ZbkotKBedwm1VEwW11oQZ3LaUiaYhQhG8rKhhDVGValnNuYKWLSnDnTAUliDYCfo8646bdoBO5ymD6uUY7KDCVnpl5eMbZ9dy5SeZzcEV51ng3Szgs0kyaptAr7V3DnSSNNtcC7Jr837fJvibTfZTDjZq6LOL4DdRZqbmBNdVJj_MpA4-xgDmfhaC5W6Zksj9MjP79uHw9-Td9jJQzsCt7WF7WEle_9wLfpr53Tv-beZwzaN_Ib2RyuX600P1kw8P-o2deQr-_6l_ARxT21U</recordid><startdate>201011</startdate><enddate>201011</enddate><creator>Lu, Hsiao-Ming</creator><creator>Mann, Greg</creator><creator>Cascio, Ethan</creator><general>American Association of Physicists in Medicine</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><scope>OTOTI</scope><scope>5PM</scope></search><sort><creationdate>201011</creationdate><title>Investigation of an implantable dosimeter for single-point water equivalent path length verification in proton therapy</title><author>Lu, Hsiao-Ming ; Mann, Greg ; Cascio, Ethan</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c6309-c8248da0b561ae6cc13f0bb2389918a10752f391a5ab3644aeb37230d8f2e7e83</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2010</creationdate><topic>60 APPLIED LIFE SCIENCES</topic><topic>ACCURACY</topic><topic>Algorithms</topic><topic>BEAM CURRENTS</topic><topic>BEAM PULSERS</topic><topic>BEAMS</topic><topic>Biomedical engineering</topic><topic>BRAGG CURVE</topic><topic>Collisional energy loss</topic><topic>DEPTH DOSE DISTRIBUTIONS</topic><topic>DOSEMETERS</topic><topic>Dose‐volume analysis</topic><topic>dosimeters</topic><topic>DOSIMETRY</topic><topic>Dosimetry/exposure assessment</topic><topic>Electric fields</topic><topic>Electric measurements</topic><topic>Humans</topic><topic>IN VIVO</topic><topic>in vivo dosimetry</topic><topic>INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY</topic><topic>Ionization chambers</topic><topic>LET dependence</topic><topic>Models, Statistical</topic><topic>Modulators</topic><topic>MOSFET</topic><topic>MOSFETs</topic><topic>particle detectors</topic><topic>particle therapy</topic><topic>prosthetics</topic><topic>Proton therapy</topic><topic>PROTONS</topic><topic>Protons - therapeutic use</topic><topic>Radiation detectors</topic><topic>Radiation Dosage</topic><topic>RADIATION DOSES</topic><topic>RADIATION PROTECTION AND DOSIMETRY</topic><topic>radiation therapy</topic><topic>Radiation Therapy Physics</topic><topic>RADIOLOGY AND NUCLEAR MEDICINE</topic><topic>Radiometry - instrumentation</topic><topic>Radiometry - methods</topic><topic>RADIOTHERAPY</topic><topic>Radiotherapy Dosage</topic><topic>range uncertainty</topic><topic>Reproducibility of Results</topic><topic>SENSORS</topic><topic>Therapeutic applications, including brachytherapy</topic><topic>Time Factors</topic><topic>VERIFICATION</topic><topic>WATER</topic><topic>Water - chemistry</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Lu, Hsiao-Ming</creatorcontrib><creatorcontrib>Mann, Greg</creatorcontrib><creatorcontrib>Cascio, Ethan</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><collection>OSTI.GOV</collection><collection>PubMed Central (Full Participant titles)</collection><jtitle>Medical physics (Lancaster)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Lu, Hsiao-Ming</au><au>Mann, Greg</au><au>Cascio, Ethan</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Investigation of an implantable dosimeter for single-point water equivalent path length verification in proton therapy</atitle><jtitle>Medical physics (Lancaster)</jtitle><addtitle>Med Phys</addtitle><date>2010-11</date><risdate>2010</risdate><volume>37</volume><issue>11</issue><spage>5858</spage><epage>5866</epage><pages>5858-5866</pages><issn>0094-2405</issn><eissn>2473-4209</eissn><eissn>0094-2405</eissn><coden>MPHYA6</coden><abstract>Purpose:
In vivo range verification in proton therapy is highly desirable. A recent study suggested that it was feasible to use point dose measurement for in vivo beam range verification in proton therapy, provided that the spread-out Bragg peak dose distribution is delivered in a different and rather unconventional manner. In this work, the authors investigate the possibility of using a commercial implantable dosimeter with wireless reading for this particular application.
Methods:
The traditional proton treatment technique delivers all the Bragg peaks required for a SOBP field in a single sequence, producing a constant dose plateau across the target volume. As a result, a point dose measurement anywhere in the target volume will produce the same value, thus providing no information regarding the water equivalent path length to the point of measurement. However, the same constant dose distribution can be achieved by splitting the field into a complementary pair of subfields, producing two oppositely “sloped” depth-dose distributions, respectively. The ratio between the two distributions can be a sensitive function of depth and measuring this ratio at a point inside the target volume can provide the water equivalent path length to the dosimeter location. Two types of field splits were used in the experiment, one achieved by the technique of beam current modulation and the other by manipulating the location and width of the beam pulse relative to the range modulator track. Eight MOSFET-based implantable dosimeters at four different depths in a water tank were used to measure the dose ratios for these field pairs. A method was developed to correct the effect of the well-known LET dependence of the MOSFET detectors on the depth-dose distributions using the columnar recombination model. The LET-corrected dose ratios were used to derive the water equivalent path lengths to the dosimeter locations to be compared to physical measurements.
Results:
The implantable dosimeters measured the dose ratios with a reasonable relative uncertainty of 1%–3% at all depths, except when the ratio itself becomes very small. In total, 55% of the individual measurements reproduced the water equivalent path lengths to the dosimeters within 1 mm. For three dosimeters, the difference was consistently less than 1 mm. Half of the standard deviations over the repeated measurements were equal or less than 1 mm.
Conclusions:
With a single fitting parameter, the LET-correction method worked remarkably well for the MOSFET detectors. The overall results were very encouraging for a potential method ofin vivo beam range verification with millimeter accuracy. This is sufficient accuracy to expand range of clinical applications in which the authors could use the distal fall off of the proton depth dose for tight margins.</abstract><cop>United States</cop><pub>American Association of Physicists in Medicine</pub><pmid>21158298</pmid><doi>10.1118/1.3504609</doi><tpages>9</tpages><oa>free_for_read</oa></addata></record> |
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| ispartof | Medical physics (Lancaster), 2010-11, Vol.37 (11), p.5858-5866 |
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| subjects | 60 APPLIED LIFE SCIENCES ACCURACY Algorithms BEAM CURRENTS BEAM PULSERS BEAMS Biomedical engineering BRAGG CURVE Collisional energy loss DEPTH DOSE DISTRIBUTIONS DOSEMETERS Dose‐volume analysis dosimeters DOSIMETRY Dosimetry/exposure assessment Electric fields Electric measurements Humans IN VIVO in vivo dosimetry INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY Ionization chambers LET dependence Models, Statistical Modulators MOSFET MOSFETs particle detectors particle therapy prosthetics Proton therapy PROTONS Protons - therapeutic use Radiation detectors Radiation Dosage RADIATION DOSES RADIATION PROTECTION AND DOSIMETRY radiation therapy Radiation Therapy Physics RADIOLOGY AND NUCLEAR MEDICINE Radiometry - instrumentation Radiometry - methods RADIOTHERAPY Radiotherapy Dosage range uncertainty Reproducibility of Results SENSORS Therapeutic applications, including brachytherapy Time Factors VERIFICATION WATER Water - chemistry |
| title | Investigation of an implantable dosimeter for single-point water equivalent path length verification in proton therapy |
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