老年帕金森病患者脑深部电刺激术后神经认知延迟恢复预测模型列线图构建与验证

doi:10.3969/j.issn.1003-9198.2026.04.016

Abstract

Abstract: Objective To construct a nomogram risk prediction model for delayed neurocognitive recovery (dNCR) in elderly patients with Parkinson’s disease (PD) after subthalamic nucleus (STN) deep brain stimulation (DBS). Methods A retrospective analysis was conducted on 291 elderly PD patients who underwent STN-DBS treatment at Nanjing Brain Hospital from 2016 to 2024. The characteristic variables were selected based on the data of patients with or without dNCR after STN-DBS. Fifteen characteristics, including prior repetitive transcranial magnetic stimulation(rTMS), disease duration, years of education, levodopa-equivalent daily dose (LEDD), scores of Hamilton Anxiety Scale(HAMA), Hamilton Depression Scale(HAMD), Mini-Mental State Examination (MMSE), Montreal Cognitive Assessment(MoCA), total cholesterol, and histories of hypertension, diabetes, cerebral infarction, and brain atrophy were enrolled in multivariable logistic regression analysis to construct a prediction nomogram model, and a calibration curve was drawn to evaluate the accuracy of the model. Results There were 89(30.58%) patients presenting with dNCR after STN-DBS. Multivariable logistic regression model identified LEDD, baseline MMSE score, years of education, rMST history, and brain atrophy as the influencing factors for dNCR after STN-DBS (all P<0.05). The model demonstrated good discriminative ability and calibration upon bootstrap validation (500 replicates), and showed consistency between the actual probability and the predicted probability. Conclusions Higher MMSE score, longer education duration, and previous rTMS treatment independently reduce the risk of post-operative dNCR, whereas elevated LEDD and brain atrophy are the risk factors. The constructed nomogram model showed robust discrimination and calibration, providing a clinically useful tool for individualized risk assessment before STN-DBS in elderly PD patients.

Key words: deep brain stimulation, delayed neurocognitive recovery, Parkinson’s disease, prediction model, aged

CLC Number:

R 749.1

YANG Yao, WAN Meiping, ZHANG Wenbin, LUO Yuanrong. Construction and validation of a nomogram for predicting delayed recovery of neurocognitive function after deep brain stimulation in elderly patients with Parkinson’s disease[J]. Practical Geriatrics, 2026, 40(4): 411-416.

References

[1] SCHALKAMP A K, PEALL K J, HARRISON N A, et al. Wearable movement-tracking data identify Parkinson’s disease years before clinical diagnosis[J]. Nat Med, 2023, 29(8):2048-2056.
[2] GEORGIEV D, ROŠKAR S, ČUŠ A, et al. STN-DBS increases proactive but not retroactive interference during verbal learning in PD[J]. Mov Disord, 2021, 36(4):1010-1015.
[3] 中华医学会神经病学分会帕金森病及运动障碍学组,中国医师协会神经内科医师分会帕金森病及运动障碍学组.中国帕金森病治疗指南(第四版)[J]. 中华神经科杂志,2020,53(12):973-986.
[4] KWON D K, KWATRA M, WANG J, et al. Levodopa-induced dyskinesia in Parkinson’s disease:pathogenesis and emerging treatment strategies[J]. Cells, 2022, 11(23):3736.
[5] HANSEN C A, MILLER D R, ANNARUMMA S, et al. Levodopa-induced dyskinesia:a historical review of Parkinson’s disease, dopamine, and modern advancements in research and treatment[J]. J Neurol, 2022, 269(6):2892-2909.
[6] DILMEN O K, MECO B C, EVERED L A, et al. Postoperative neurocognitive disorders:a clinical guide[J]. J Clin Anesth, 2024, 92:111320.
[7] KONG H, XU L M, WANG D X. Perioperative neurocognitive disorders:a narrative review focusing on diagnosis, prevention, and treatment[J]. CNS Neurosci Ther, 2022, 28(8):1147-1167.
[8] TOLOSA E, GARRIDO A, SCHOLZ S W, et al. Challenges in the diagnosis of Parkinson’s disease[J]. Lancet Neurol, 2021, 20(5):385-397.
[9] DI BIASE L, DI SANTO A, CAMINITI M L, et al. Gait analysis in Parkinson’s disease:an overview of the most accurate markers for diagnosis and symptoms monitoring[J]. Sensors, 2020, 20(12):3529.
[10] JAHANSHAHI M, LEIMBACH F, RAWJI V. Short and long-term cognitive effects of subthalamic deep brain stimulation in Parkinson’s disease and identification of relevant factors[J]. J Parkinsons Dis, 2022, 12(7):2191-2209.
[11] CHANG B, NI C, ZHANG W, et al. Nomogram to predict cognitive state improvement after deep brain stimulation for Parkinson’s disease[J]. Brain Sci, 2022, 12(6):759.
[12] MILLS K A, DONOHUE K, SWAMINATHAN A, et al. Neuropsychological predictors of patient-reported cognitive decline after deep brain stimulation in Parkinson’s disease[J]. J Clin Exp Neuropsychol, 2019, 41(3):219-228.
[13] 中华医学会神经病学分会帕金森病及运动障碍学组,中国医师协会神经内科医师分会帕金森病及运动障碍专业委员会. 中国帕金森病的诊断标准(2016版)[J]. 中华神经科杂志,2016,49(4):268-271.
[14] JIN Z, HU J, MA D. Postoperative delirium:perioperative assessment, risk reduction, and management[J]. Br J Anaesth, 2020, 125(4):492-504.
[15] 罗宁, 叶春艳, 刘星扬, 等. 腹腔镜结直肠癌手术术后神经认知恢复延迟风险预测模型的建立与验证[J]. 中国普通外科杂志, 2024, 33(4):603-611.
[16] 李仁华, 陈娜, 王锷, 等. 老年患者术前睡眠障碍与术后神经认知恢复延迟的相关性[J]. 中南大学学报(医学版), 2021, 46(11):1251-1259.
[17] HOLEWIJN R A, VERBAAN D, VAN DEN MUNCKHOF P M, et al. General anesthesia vs local anesthesia in microelectrode recording-guided deep-brain stimulation for parkinson disease:the GALAXY randomized clinical trial[J]. JAMA Neurol, 2021, 78(10):1212-1219.
[18] KUHN J, WONG J K, OKUN M S, et al. Connectomic imaging to predict and prevent cognitive decline after subthalamic DBS:next steps[J]. Brain, 2022, 145(4):1204-1206.
[19] YOU Z, WU Y Y, WU R, et al. Efforts of subthalamic nucleus deep brain stimulation on cognitive spectrum:from explicit to implicit changes in the patients with Parkinson’s disease for 1 year[J]. CNS Neurosci Ther, 2020, 26(9):972-980.
[20] PLANCHE V, MUNSCH F, PEREIRA B, et al. Anatomical predictors of cognitive decline after subthalamic stimulation in Parkinson’s disease[J]. Brain Struct Funct, 2018, 223(7):3063-3072.
[21] NIMURA T, NAGAMATSU K I, ANDO T, et al. An investigation into the effects and prognostic factors of cognitive decline following subthalamic nucleus stimulation in patients with Parkinson’s disease[J]. J Clin Neurosci, 2017, 44:164-168.
[22] KNAAK C, BROCKHAUS W R, SPIES C, et al. Presurgical cognitive impairment is associated with postoperative delirium and postoperative cognitive dysfunction[J]. Minerva Anestesiol, 2020, 86(4):394-403.
[23] 张维亮, 季加富, 苏帆, 等. 围术期神经认知障碍患者远期认知功能下降的研究进展[J]. 临床麻醉学杂志, 2023, 39(9):983-986.
[24] 谢婧, 韩剑虹. 脑深部电刺激对帕金森病精神和认知影响的研究进展[J]. 医学理论与实践, 2021, 34(4):546, 562-564.
[25] KIM H J, JEON B S, PAEK S H, et al. Long-term cognitive outcome of bilateral subthalamic deep brain stimulation in Parkinson’s disease[J]. J Neurol, 2014, 261(6):1090-1096.
[26] FEINKOHL I, WINTERER G, SPIES C D, et al. Cognitive reserve and the risk of postoperative cognitive dysfunction[J]. Dtsch Arztebl Int, 2017, 114(7):110-117.
[27] 陆燕艳, 蒋培余, 江山秀. 老年病人术后认知障碍的影响因素及其干预措施研究进展[J]. 循证护理, 2022, 8(19):2609-2612.
[28] AARSLAND D, BATZU L, HALLIDAY G M, et al. Parkinson disease-associated cognitive impairment[J]. Nat Rev Dis Primers, 2021, 7(1):47.
[29] 熊莉君, 杨燕, 王芳. 重复经颅磁刺激联合心理干预治疗帕金森病抑郁患者的疗效观察[J]. 中华物理医学与康复杂志, 2023,45(4):312-316.
[30] 赵玉欣, 张德旗, 毕鸿雁. 非侵入性脑刺激不同刺激方式对帕金森病患者认知功能影响的网状Meta分析[J]. 中国组织工程研究, 2025, 29(24):5212-5223.

Construction and validation of a nomogram for predicting delayed recovery of neurocognitive function after deep brain stimulation in elderly patients with Parkinson’s disease

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Metrics

Recommended 10

[1]	JI Junjie, ZHOU Zhonghan, LIU Gongyue, LIU Yixi, LIAO Limin. Correlation between frailty and the risk of benign prostatic hyperplasia/lower urinary tract symptoms in elderly males aged 60 and above in China [J]. Practical Geriatrics, 2026, 40(4): 325-331.
[2]	MO Sisi, YU Yanlan. Analysis of factors related to therapeutic efficacy of sacral nerve modulation in elderly patients with neurogenic lower urinary tract dysfunction [J]. Practical Geriatrics, 2026, 40(4): 340-343.
[3]	LU Shuang, LI Xia, REN Qianmeng. Risk prediction model of cognitive dysfunction in elderly patients with Parkinson’s disease based on quantitative MRI parameters [J]. Practical Geriatrics, 2026, 40(4): 362-366.
[4]	XU Zhongmei, LIU Fang, CHANG Yun, ZHENG Xuemei, SHANG Shuhua. Influence of sleep duration and social isolation on cognitive frailty in elderly patients with chronic heart failure [J]. Practical Geriatrics, 2026, 40(4): 377-381.
[5]	LIU Wen, LIU Yuting, JI Muhuo. T cell mitochondrial dysfunction link to postoperative delirium in elderly thoracic surgery patients [J]. Practical Geriatrics, 2026, 40(4): 382-388.
[6]	MENG Hanlu, SHEN Qiuyue, CHEN Junjun, CHEN Chen, XU Lili, GUO Qingyu, CHEN Min. Effect of multi-dimensional collaborative management based on frailty risk assessment on blood glucose control and health promotion behavior in elderly patients with T2DM complicated with frailty risk [J]. Practical Geriatrics, 2026, 40(4): 394-399.
[7]	QI Rongfu, XIE Tong, ZHOU Jie, ZHOU Liwu, YIN Haijian. Early application value of high tibial osteotomy combined with platelet-rich plasma in the treatment of elderly patients with medial compartment osteoarthritis [J]. Practical Geriatrics, 2026, 40(4): 400-405.
[8]	TIAN Shuyun, CHANG Lijuan, CHEN Xin, FAN Qi, MA Feifei. Research progress of artificial intelligence in emotional management for elderly care [J]. Practical Geriatrics, 2026, 40(4): 417-421.
[9]	SHI Chaoxiong, QIAN Lijun, LU Miao, PANG Sisi, WANG Sen, XIA Lili, XIAO Suwan, LI Tingru, TANG Yifan. Summary of the best evidence for polypharmacy management in elderly patients with chronic heart failure [J]. Practical Geriatrics, 2026, 40(4): 427-432.
[10]	LIU Yukun, LEI Jiawei, ZHU Chunming, ZHANG Yuqiang, WANG Jiahe. Research progress on molecular mechanism and drug target of fraity syndrome [J]. Practical Geriatrics, 2026, 40(3): 224-228.
[11]	SUN Kexin, LEI Jiawei, ZHANG Guilei, YANG Zhenrong, WANG Jiahe. Research progress on drug targets for the treatment of sarcopenia in the elderly [J]. Practical Geriatrics, 2026, 40(3): 229-233.
[12]	LI Minglin, LI Minfeng, ZENG Sanlong, LIANG Qingjing, LIU Jiye, LUO Jianwen. Research advances in drug targets for visual impairment in the elderly [J]. Practical Geriatrics, 2026, 40(3): 234-240.
[13]	XIAO Lingyi, XIAO Guojin, LIAO Shunqi, HOU Suying, LIU Lixin, XIA Lin. Insulin nasal drops for the prevention of delirium after surgery in elderly patients: a meta-analysis [J]. Practical Geriatrics, 2026, 40(3): 254-260.
[14]	XU Jiaping, HE Chao, LIN Xiaofeng, ZHANG Lixia, ZHU Zixian, KONG Li. Construction and validation of an in-hospital hypothermia risk prediction model for elderly patients with severe trauma in Emergency Department [J]. Practical Geriatrics, 2026, 40(3): 261-266.
[15]	ZHAO Xia, WANG Dongxu, LAI Xiaoxing, HUO Xiaopeng. Analysis of oral frailty prevalence and its influencing factors in hospitalized elderly patients with comorbidities [J]. Practical Geriatrics, 2026, 40(3): 267-271.