This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Macchione MA, Lechón Páez S, Strumia MC, Valente M, Mattea F. Chemical overview of gel dosimetry systems: a comprehensive review. Gels. 2022;8(10):663.MacchioneMALechón PáezSStrumiaMCValenteMMatteaF.Chemical overview of gel dosimetry systems: a comprehensive review..2022;8(10):663.Search in Google Scholar
Azadeh P, Amiri S, Mostaar A, Joybari AY, Paydar R. Evaluation of MAGIC-f polymer gel dosimeter for dose profile measurement in small fields and stereotactic irradiation. Radiat Phys Chem. 2022;194:109991.AzadehPAmiriSMostaarAJoybariAYPaydarR.Evaluation of MAGIC-f polymer gel dosimeter for dose profile measurement in small fields and stereotactic irradiation..2022;194:109991.Search in Google Scholar
Kron T, Metcalfe P, Pope JM. Investigation of the tissue equivalence of gels used for NMR dosimetry. Phys Med Biol. 1993;38:139–50.KronTMetcalfePPopeJM.Investigation of the tissue equivalence of gels used for NMR dosimetry..1993;38:139–50.Search in Google Scholar
Al-Kahtani HA, Jaswir I, Ismail EA, Ahmed MA, Monsur Hammed A, Olorunnisola S, Octavianti F. Structural characteristics of camel-bone gelatin by demineralization and extraction. Int J Food Prop. 2017;20:11.Al-KahtaniHAJaswirIIsmailEAAhmedMAMonsur HammedAOlorunnisolaSOctaviantiF.Structural characteristics of camel-bone gelatin by demineralization and extraction..2017;20:11.Search in Google Scholar
Al-Hassan AA, Abdel-Salam AM, Al Nasiri F, Mousa HM, Nafchi AMM. J Food Meas Charact. 2021;15:4542–51.Al-HassanAAAbdel-SalamAMAl NasiriFMousaHMNafchiAMM..2021;15:4542–51.Search in Google Scholar
Ahmed MA, Al-Kahtani HA, Jaswir I, AbuTarboush H, Ismail EA. Extraction and characterization of gelatin from camel skin (potential halal gelatin) and production of gelatin nanoparticles. Saudi J Biol Sci. 2020;27(6):1596–601.AhmedMAAl-KahtaniHAJaswirIAbuTarboushHIsmailEA.Extraction and characterization of gelatin from camel skin (potential halal gelatin) and production of gelatin nanoparticles..2020;27(6):1596–601.Search in Google Scholar
Chan MF, Ayyangar K. Verification of water equivalence of FeMRI gel using Monte Carlo simulation. Med Phys. 1995;22(4):475–8.ChanMFAyyangarK.Verification of water equivalence of FeMRI gel using Monte Carlo simulation..1995;22(4):475–8.Search in Google Scholar
Keall P, Baldock C. A theoretical study of the radiological properties and water equivalence of Fricke and polymer gels used for radiation dosimetry. Australas Phys Eng.Sci Med. 1999;22:85–91.KeallPBaldockC.A theoretical study of the radiological properties and water equivalence of Fricke and polymer gels used for radiation dosimetry..1999;22:85–91.Search in Google Scholar
Schreiner LJ. Review of Fricke cel dosimeters. J Phys Conf Ser. 2004;3:9–21.SchreinerLJ.Review of Fricke cel dosimeters..2004;3:9–21.Search in Google Scholar
De Deene Y, Hurley C, Venning A, Vergote K, Mather M, Healy B, et al. A basic study of some normoxic polymer gel dosimeters. Phys Med Biol. 2002;47(19):3441–63.De DeeneYHurleyCVenningAVergoteKMatherMHealyB.A basic study of some normoxic polymer gel dosimeters..2002;47(19):3441–63.Search in Google Scholar
Gustavsson H, Bäck SÅJ, Medin J, Grusell E, Olsson LE. Linear energy transfer dependence of a normoxic polymer gel dosimeter investigated using proton beam absorbed dose measurements. Phys Med Biol. 2004;49(17):3847–55.GustavssonHBäckSÅJMedinJGrusellEOlssonLE.Linear energy transfer dependence of a normoxic polymer gel dosimeter investigated using proton beam absorbed dose measurements..2004;49(17):3847–55.Search in Google Scholar
De Deene Y. Radiation dosimetry by use of radiosensitive hydrogels and polymers: mechanisms, state-of-the-art and perspective from 3D to 4D. Gels. 2022;8:599.De DeeneY.Radiation dosimetry by use of radiosensitive hydrogels and polymers: mechanisms, state-of-the-art and perspective from 3D to 4D..2022;8:599.Search in Google Scholar
Zhang P, Jiang L, Chen H, Hu L. Recent advances in hydrogel-based sensors responding to ionizing radiation. Gels. 2022;8:238.ZhangPJiangLChenHHuL.Recent advances in hydrogel-based sensors responding to ionizing radiation..2022;8:238.Search in Google Scholar
Nezhad ZA, Geraily G. A review study on application of gel dosimeters in low energy radiation dosimetry. Appl Radiat Isot. 2022;179:110015.NezhadZAGerailyG.A review study on application of gel dosimeters in low energy radiation dosimetry..2022;179:110015.Search in Google Scholar
Gayol G, Malano F, Montenovo CR, Pérez P, Valente M. Dosimetry effects due to the presence of Fe nanoparticles for potential combination of hyperthermic cancer treatment with MRI-based image-guided radiotherapy. Int J Molec Sci. 2023;24(1):514.GayolGMalanoFMontenovoCRPérezPValenteM.Dosimetry effects due to the presence of Fe nanoparticles for potential combination of hyperthermic cancer treatment with MRI-based image-guided radiotherapy..2023;24(1):514.Search in Google Scholar
Soliman YS, Tadros SM, Beshir WB, Saad GR, Gallo S, Ali LI, Naoum MM. Study of Ag nanoparticles in a polyacrylamide hydrogel dosimeters by optical technique. Gels 2022;.8(4):222.SolimanYSTadrosSMBeshirWBSaadGRGalloSAliLINaoumMM.Study of Ag nanoparticles in a polyacrylamide hydrogel dosimeters by optical technique.2022;.8(4):222.Search in Google Scholar
Sofi MA, Sunitha S, Sofi MA, Khadheer Pasha SK, Choi D. An overview of antimicrobial and anticancer potential of silver nanoparticles. J King Saud Univ – Sci. 2022;34(2): 101791.SofiMASunithaSSofiMAKhadheer PashaSKChoiD.An overview of antimicrobial and anticancer potential of silver nanoparticles..2022;34(2):101791.Search in Google Scholar
Kortov V. Materials for thermoluminescent dosimetry: current status and future trends. Radiat Meas. 2007;42:576–81.KortovV.Materials for thermoluminescent dosimetry: current status and future trends..2007;42:576–81.Search in Google Scholar
Kron T. Thermoluminescence dosimetry and its applications in medicine–Part 1: physics, materials and equipment. Australas Phys Eng Sci Med. 1994;17:175–99.KronT.Thermoluminescence dosimetry and its applications in medicine–Part 1: physics, materials and equipment..1994;17:175–99.Search in Google Scholar
Kry SF, Alvarez P, Cygler JE, DeWerd LA, Howell RM, Meeks S, et al. AAPM TG 191: clinical use of luminescent dosimeters: TLDs and OSLDs. Med Phys. 2020;47:e19–e51.KrySFAlvarezPCyglerJEDeWerdLAHowellRMMeeksS.AAPM TG 191: clinical use of luminescent dosimeters: TLDs and OSLDs..2020;47:e19–e51.Search in Google Scholar
Lye J, Dunn L, Kenny J, Lehmann J, Kron T, Oliver C, et al. Remote auditing of radiotherapy facilities using optically stimulated luminescence dosimeters. Med Phys. 2014;41:032102.LyeJDunnLKennyJLehmannJKronTOliverC.Remote auditing of radiotherapy facilities using optically stimulated luminescence dosimeters..2014;41:032102.Search in Google Scholar
Poirier Y, Kuznetsova S, Villarreal-Barajas JE. Characterization of nanodot optically stimulated luminescence detectors and high-sensitivity MCP-N thermoluminescent detectors in the 40–300 kVp energy range. Med Phys. 2018;45:402–13.PoirierYKuznetsovaSVillarreal-BarajasJE.Characterization of nanodot optically stimulated luminescence detectors and high-sensitivity MCP-N thermoluminescent detectors in the 40–300 kVp energy range..2018;45:402–13.Search in Google Scholar
Damulira E, Yusoff MNS, Omar AF, Mohd Taib NH. A review: photonic devices used for dosimetry in medical radiation. Sensors. 2010;19:2226.DamuliraEYusoffMNSOmarAFMohd TaibNH.A review: photonic devices used for dosimetry in medical radiation..2010;19:2226.Search in Google Scholar
Inoue K, Yamaguchi I, Natsuhori M. Low-dose radiation effects on animals and ecosystems. In: Fukumoto M, editor. Preliminary study on electron spin resonance dosimetry using affected cattle teeth due to the Fukushima Daiichi nuclear power plant accident. Singapore: Springer, 2020.InoueKYamaguchiINatsuhoriM.Low-dose radiation effects on animals and ecosystems. In:FukumotoM, editor..Singapore:Springer,2020.Search in Google Scholar
Kinoshita A, Baffa O, Mascarenhas S. Electron spin resonance (ESR) dose measurement in bone of Hiroshima A-bomb victim. PLoS ONE 2018;13:e0192444.KinoshitaABaffaOMascarenhasS.Electron spin resonance (ESR) dose measurement in bone of Hiroshima A-bomb victim.2018;13:e0192444.Search in Google Scholar
Klein JS, Sun C, Pratx G. Radioluminescence in biomedicine: physics, applications, and models. Phys Med Biol. 2019;64:04TR01.KleinJSSunCPratxG.Radioluminescence in biomedicine: physics, applications, and models..2019;64:04TR01.Search in Google Scholar
Petisiwaveth P, Wanotayan R, Damrongkijudom N, Ninlaphruk S, Kladsomboon, S. Dosimetric performance of poly(vinyl alcohol)/silver nanoparticles hybrid nanomaterials for colorimetric sensing of gamma radiation. Nanomaterials 2022;12(7):1088.PetisiwavethPWanotayanRDamrongkijudomNNinlaphrukSKladsomboonS.Dosimetric performance of poly(vinyl alcohol)/silver nanoparticles hybrid nanomaterials for colorimetric sensing of gamma radiation.2022;12(7):1088.Search in Google Scholar
Titus D, Samuel EJJ, Srinivasan K, Roopan SM, Madhu CS. Silver nitrate-based gel dosimeter. J Phys: Conference Series. 847 012066.TitusDSamuelEJJSrinivasanKRoopanSMMadhuCS.Silver nitrate-based gel dosimeter.:Conference Series.847 012066.Search in Google Scholar
Vedelago J, Mattea F, Valente M. Integration of Fricke gel dosimetry with Ag nanoparticles for experimental dose enhancement determination in theranostics, Appl Radiat Isot. 2018;141:182–6.VedelagoJMatteaFValenteM.Integration of Fricke gel dosimetry with Ag nanoparticles for experimental dose enhancement determination in theranostics,.2018;141:182–6.Search in Google Scholar
Badi N, Mekala R, Khasim S, Roy AS, Ignatiev A. Enhanced dielectric performance in PVDF/Al-Al2O3 core-shell nanocomposites. J Mater Sci: Mater Electron. 2018;29:10593–9.BadiNMekalaRKhasimSRoyASIgnatievA.Enhanced dielectric performance in PVDF/Al-Al2O3 core-shell nanocomposites..2018;29:10593–9.Search in Google Scholar
Wong C. Polymers for electronic and photonic application. Amsterdam: Elsevier; 2013.WongC..Amsterdam:Elsevier;2013.Search in Google Scholar
Nafee SS, Hamdalla TA, Shaheen SA. FTIR and optical properties for irradiated PVA–GdCl3 and its possible use in dosimetry. Phase Transit. 2017;90:439.NafeeSSHamdallaTAShaheenSA.FTIR and optical properties for irradiated PVA–GdCl3 and its possible use in dosimetry..2017;90:439.Search in Google Scholar
Rashad M, Hanafy TA, Issa SAM. Structural, electrical and radiation shielding properties of polyvinyl alcohol doped with different nanoparticles. J Mater Sci—Mater Electron. 2020;31:15192.RashadMHanafyTAIssaSAM.Structural, electrical and radiation shielding properties of polyvinyl alcohol doped with different nanoparticles..2020;31:15192.Search in Google Scholar
Al Misned G, Akman F, AbuShanab WS, Tekin HO, Kaçal MR, Issa SAM, et al. Novel Cu/Zn reinforced polymer composites: experimental characterization for radiation protection efficiency (RPE) and shielding properties for alpha, proton, neutron, and gamma radiations. Polymers. 2021;13:3157.Al MisnedGAkmanFAbuShanabWSTekinHOKaçalMRIssaSAM.Novel Cu/Zn reinforced polymer composites: experimental characterization for radiation protection efficiency (RPE) and shielding properties for alpha, proton, neutron, and gamma radiations..2021;13:3157.Search in Google Scholar
Abdalsalam AH, Sakar E, Kaky KM, Mhareb MHA, Sakar BC, Sayyed MI, Gürol A. Investigation of gamma ray attenuation features of bismuth oxide nano powder reinforced high-density polyethylene matrix composites. Radiat Phys Chem. 2020;168:108537.AbdalsalamAHSakarEKakyKMMharebMHASakarBCSayyedMIGürolA.Investigation of gamma ray attenuation features of bismuth oxide nano powder reinforced high-density polyethylene matrix composites..2020;168:108537.Search in Google Scholar
Akman F, Kaçal MR, Almousa N, Sayyed MI, Polat H. Gamma-ray attenuation parameters for polymer composites reinforced with BaTiO3 and CaWO4 compounds. Prog Nucl Energy. 2020;121:103257.AkmanFKaçalMRAlmousaNSayyedMIPolatH.Gamma-ray attenuation parameters for polymer composites reinforced with BaTiO3 and CaWO4 compounds..2020;121:103257.Search in Google Scholar
Hamdalla TA, Nafee SS. Bragg wavelength shift for irradiated polymer fiber Bragg grating. Opt Laser Technol. 2017;74:167.HamdallaTANafeeSS.Bragg wavelength shift for irradiated polymer fiber Bragg grating..2017;74:167.Search in Google Scholar
Pai S, Das IJ, Dempsey JF, Lam KL, Losasso TJ, Olch AJ, et al. TG-69: radiographic film for megavoltage beam dosimetry. Med Phys. 2007;34:2228.PaiSDasIJDempseyJFLamKLLosassoTJOlchAJ.TG-69: radiographic film for megavoltage beam dosimetry..2007;34:2228.Search in Google Scholar
Hassan N, Ahmad T, Zain NM, Awang SR. Identification of bovine, porcine and fish gelatin signatures using chemometrics fuzzy graph method. Sci Rep. 2021;11:9793.HassanNAhmadTZainNMAwangSR.Identification of bovine, porcine and fish gelatin signatures using chemometrics fuzzy graph method..2021;11:9793.Search in Google Scholar
Hashim DM, Che Man YB, Norakasha R, Shuhaimi M, Salmah Y, Syahariza ZA. Potential use of Fourier transform infrared spectroscopy for differentiation of bovine and porcine gelatins. Food Chem. 2010;118(3):856–60.HashimDMChe ManYBNorakashaRShuhaimiMSalmahYSyaharizaZA.Potential use of Fourier transform infrared spectroscopy for differentiation of bovine and porcine gelatins..2010;118(3):856–60.Search in Google Scholar
Zilhadia KF, Betha OS, Supandi S. Diferensiasi gelatin sapi dan gelatin babi pada gummy vitamin C nmenggunakan methode kombinasi spektroskopi Fourier transform infrared (FTIR) dan principal component analysis (PCA). Pharm Sci Res. 2018;5(2):90–6.ZilhadiaKFBethaOSSupandiS.Diferensiasi gelatin sapi dan gelatin babi pada gummy vitamin C nmenggunakan methode kombinasi spektroskopi Fourier transform infrared (FTIR) dan principal component analysis (PCA)..2018;5(2):90–6.Search in Google Scholar
Barth A. Infrared spectroscopy of proteins. Biochim Biophys Acta (BBA)-Bioenerg. 2007;1767:1073–101.BarthA.Infrared spectroscopy of proteins..2007;1767:1073–101.Search in Google Scholar
Al-Hassan AA, Abdel-Salam A.M, Al Nasiri F, Mousa HM, Nafch AM. Extraction and characterization of gelatin developed from camel bones. J Food Meas Charact. 2021;15:4542–51.Al-HassanAAAbdel-SalamA.MAl NasiriFMousaHMNafchAM.Extraction and characterization of gelatin developed from camel bones..2021;15:4542–51.Search in Google Scholar
Al-Kahtani HA, Jaswir I, Ismail EA, Ahmed MA, Hammed AM, Olorunnisola S, Octavianti F. Structural characteristics of camel-bone gelatin by demineralization and extraction. Int J Food Prop. 2017;20:2559–68.Al-KahtaniHAJaswirIIsmailEAAhmedMAHammedAMOlorunnisolaSOctaviantiF.Structural characteristics of camel-bone gelatin by demineralization and extraction..2017;20:2559–68.Search in Google Scholar
Fawale OS, Abuibaid A, Hamed F, Kittiphattanabawon P, Maqsood S. Molecular, structural, and rheological characterization of camel skin gelatin extracted using different pretreatment conditions. Foods. 2021;10: 1563.FawaleOSAbuibaidAHamedFKittiphattanabawonPMaqsoodS.Molecular, structural, and rheological characterization of camel skin gelatin extracted using different pretreatment conditions..2021;10:1563.Search in Google Scholar
Kong J, Yu S. Fourier transform infrared spectroscopic analysis of protein secondary structures. Acta Biochim Biophys Sin. 2007;39:549–59.KongJYuS.Fourier transform infrared spectroscopic analysis of protein secondary structures..2007;39:549–59.Search in Google Scholar
Nur Hanani ZA, Roos YH, Kerry JP. Fourier transform infrared (FTIR) spectroscopic analysis of biodegradable gelatin films immersed in water. Int Congr Eng Food, Proc. 2011.Nur HananiZARoosYHKerryJP.Fourier transform infrared (FTIR) spectroscopic analysis of biodegradable gelatin films immersed in water..2011.Search in Google Scholar
Alim-Al-Razy M, Bayazid GMA, Rahman RU, Bosu R, Shamma SS. Silver nanoparticle synthesis, UV-Vis spectroscopy to find particle size and measure resistance of colloidal solution. J Phys. 2020;1706:012020.Alim-Al-RazyMBayazidGMARahmanRUBosuRShammaSS.Silver nanoparticle synthesis, UV-Vis spectroscopy to find particle size and measure resistance of colloidal solution..2020;1706:012020.Search in Google Scholar
Fuliful F, Hashim A, Madlool R. Calculating the X-ray attenuation coefficients of gelatin as human tissue substitute. Austral J Basic Appl Sci. 2017;11:21.FulifulFHashimAMadloolR.Calculating the X-ray attenuation coefficients of gelatin as human tissue substitute..2017;11:21.Search in Google Scholar