第44卷第7期
               ·1016 ·                         南   京 医 科       大 学      学 报                        2024年7月


                   of magnetic resonance imaging for local staging of pros⁃  index lesion radiomics and machine learning for detection
                   tate cancer：a diagnostic meta ⁃ analysis［J］. Eur Urol，  of extraprostatic extension of disease：a multicenter

                   2016，70（2）：233-245                                study［J］. Eur Radiol，2021，31（10）：7575-7583
             ［36］STANZIONE A，CUOCOLO R，COCOZZA S，et al. Detec⁃  ［47］FAN X H，XIE N，CHEN J W，et al. Multiparametric MRI
                   tion of extraprostatic extension of cancer on biparametric  and machine learning based radiomic models for preoper⁃
                   MRI combining texture analysis and machine learning：  ative prediction of multiple biological characteristics in
                   preliminary results［J］. Acad Radiol，2019，26（10）：  prostate cancer［J］. Front Oncol，2022，12：839621
                   1338-1344                                    ［48］ZHONG Q Z，LONG L H，LIU A，et al. Radiomics of mul⁃
             ［37］MA S，XIE H H，WANG H H，et al. Preoperative predic⁃   tiparametric MRI to predict biochemical recurrence of lo⁃
                   tion of extracapsular extension：radiomics signature based  calized prostate cancer after radiation therapy［J］. Front
                   on magnetic resonance imaging to stage prostate cancer［J］.  Oncol，2020，10：731
                   Mol Imaging Biol，2020，22（3）：711-721          ［49］LI L，SHIRADKAR R，LEO P，et al. A novel imaging
             ［38］ LOSNEGÅRD A，REISAETER L A R，HALVORSEN O            based nomogram for predicting post⁃surgical biochemical
                   J，et al. Magnetic resonance radiomics for prediction of ex⁃  recurrence and adverse pathology of prostate cancer from
                   traprostatic extension in non⁃favorable intermediate⁃ and  pre⁃operative bi⁃parametric MRI［J］. EBio Med，2021，
                   high⁃risk prostate cancer patients［J］. Acta Radiol，2020，  63：103163
                   61（11）：1570-1579                             ［50］SHIRADKAR R，PODDER T K，ALGOHARY A，et al.
             ［39］MA S，XIE H H，WANG H H，et al. MRI⁃based radiomics    Radiomics based targeted radiotherapy planning（Rad ⁃
                   signature for the preoperative prediction of extracapsular  TRaP）：a computational framework for prostate cancer
                   extension of prostate cancer［J］. J Magn Reson Imaging，  treatment planning with MRI［J］. Radiat Oncol，2016，11
                   2019，50（6）：1914-1925                             （1）：148
             ［40］XU L L，ZHANG G，ZHAO L，et al. Radiomics based on  ［51］DANIEL M，KUESS P，ANDRZEJEWSKI P，et al. Impact
                   multiparametric magnetic resonance imaging to predict  of androgen deprivation therapy on apparent diffusion co⁃
                   extraprostatic extension of prostate cancer［J］. Front On⁃  efficient and T2W MRI for histogram and texture analysis
                   col，2020，10：940                                   with respect to focal radiotherapy of prostate cancer［J］.
             ［41］HE D，WANG X M，FU C C，et al. MRI⁃based radiomics     Al，2019，195（5）：402-411
                   models to assess prostate cancer，extracapsular extension  ［52］ABDOLLAHI H，TANHA K，MOFID B，et al. MRI ra⁃
                   and positive surgical margins［J］. Cancer Imaging，2021，  diomic analysis of IMRT⁃induced bladder wall changes in
                   21（1）：46                                          prostate cancer patients：a relationship with radiation
             ［42］BAI H L，XIA W，JI X F，et al. Multiparametric magnetic  dose and toxicity［J］. J Med Imaging Radiat Sci，2019，50
                   resonance imaging⁃based peritumoral radiomics for preop⁃  （2）：252-260
                   erative prediction of the presence of extracapsular exten⁃  ［53］ABDOLLAHI H，MOFID B，SHIRI I，et al. Machine learn⁃
                   sion with prostate cancer［J］. J Magn Reson Imaging，  ing⁃based radiomic models to predict intensity⁃modulated
                   2021，54（4）：1222-1230                              radiation therapy response，Gleason score and stage in
             ［43］ALGOHARY A，SHIRADKAR R，PAHWA S，et al. Com⁃          prostate cancer［J］. Radiol Med，2019，124（6）：555-567
                   bination of peri⁃tumoral and intra⁃tumoral radiomic fea⁃  ［54］SULLIVAN L，WILLIAMS S G，TAI K H，et al. Urethral
                   tures on Bi⁃parametric MRI accurately stratifies prostate  stricture following high dose rate brachytherapy for pros⁃
                   cancer risk：a multi⁃site study［J］. Cancers，2020，12（8）：  tate cancer［J］. Radiother Oncol，2009，91（2）：232-236
                   2200                                         ［55］TSANG Y M，VIGNARAJAH D，MCWILLIAM A，et al. A
             ［44］ZHAI T，HU L，MA W，et al. Peri⁃prostatic adipose tissue  pilot study on dosimetric and radiomics analysis of ure⁃
                   measurements using MRI predict prostate cancer aggres⁃  thral strictures following HDR brachytherapy as monother⁃
                   siveness in men undergoing radical prostatectomy［J］. J  apy for localized prostate cancer［J］. Br J Radiol，2020，93
                   Endocrinol Invest，2021，44（2）：287-296             （1106）：20190760
             ［45］SALJI M，HENDRY J，PATEL A，et al. Peri⁃prostatic fat  ［56］ABDOLLAHI H，MAHDAVI S R，SHIRI I，et al. Magnet⁃
                   volume measurement as a predictive tool for castration re⁃  ic resonance imaging radiomic feature analysis of radiation
                   sistance in advanced prostate cancer［J］. Eur Urol Focus，  ⁃induced femoral head changes in prostate cancer radio⁃
                   2018，4（6）：858-866                                 therapy［J］. J Cancer Res Ther，2019，15（Supplement）：
             ［46］CUOCOLO R，STANZIONE A，FALETTI R，et al. MRI          S11-S19