Robot-assisted placement of pedicle screws for treatment of spine degenerative diseases: A Meta-Analysis

doi:10.3877/cma.j.issn.2096-0263.2019.01.008

Abstract

Abstract:

Objective

To compare the accuracy and security between robot-assisted and fluoroscopy-guided pedicle screw placement s in the treatment of spine degenerative disease.

Methods

This study included clinical trials published both at demestic and abroad from April 2008 to April 2018. The retrieval was performed inonline databases include Embase, Pubmed, CNKI, CQVIP, Wanfang Data, etc. Based on the search strategy, a total of 377 related literatures were retrieved and 10 foreign documents and 1 Chinese document were included. After data extraction, statistical software Review manager 5.3 was used for data-analysis.

Results

It was found that when the pedicle screws were used to treat elderly patients with degenerative diseases of the spine, the accuracy of placement of the robot-assisted group was superior to that of the fluoroscopy-guided group (95% CI: 1.38-2.43, P<0.001). The robot-assisted number of adverse events (95% CI: 0.22-0.90, P=0.02) and revisions (95% CI: 0.17-0.91, P=0.03) were less than the fluoroscopy guidance group. But fluoroscopy exposure was more than the robot-assisted group (95% CI: 0.09-0.89, P=0.02). Other differences between the two groups were not statistically significant.

Conclusions

In the treatment of elderly degenerative diseases of the spine, robot-assisted pedicle screw implantation has higher accuracy and fewer complications than conventional fluoroscopy guided. Although intraoperative fluoroscopy exposure is slightly higher the fluoroscopy-guided group, robot-assisted technology is still a safe and reliable treatment option.

Key words: Spinal diseases, Surgery, computer-assisted, Pedicle screws, Robot-assisted

Pengfei Han, Zhiliang Zhang, Chenglong Chen, Taoyu Chen, Xiaodong Li, Pengcui Li, Lei Wei, Zhi Lyu, Xiaochun Wei. Robot-assisted placement of pedicle screws for treatment of spine degenerative diseases: A Meta-Analysis[J]. Chinese Journal of Geriatric Orthopaedics and Rehabilitation(Electronic Edition), 2019, 05(01): 39-47.

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Figures/Tables 7

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纳入研究	类型	国家	年份	组别	例数	年龄（岁）	性别（男/女）	结局指标	改良Jadad质量评价
Hyun等^[9]	随机对照	韩国	2016	RA	30	66.5	9/21	（1）（4）（5）（6）（7）（8）（9）	7
Hyun等^[9]	随机对照	韩国	2016	FG	30	66.8	8/22	（1）（4）（5）（6）（7）（8）（9）	7
Kantelhardt等^[10]	回顾性	德国	2011	RA	55	63.1	52/60	（1）（5）（8）（9）	3
Kantelhardt等^[10]	回顾性	德国	2011	FG	57	63.1	52/60	（1）（5）（8）（9）	3
Keric等^[11]	回顾性	德国	2016	RA	66	72.3±11.1	36/30	（1）（2）（3）（5）（6）（7）（8）（9）	2
Keric等^[11]	回顾性	德国	2016	FG	24	68±11.23	13/11	（1）（2）（3）（5）（6）（7）（8）（9）	2
Kim等^[12]	随机对照	韩国	2015	RA	20	64.4±11.9	11/9	（1）（8）	6
Kim等^[12]	随机对照	韩国	2015	FG	20	64.7±8.6	8/12	（1）（8）	6
Kim等^[13]	回顾性	韩国	2016	RA	37	65.4±10.4	19/18	（1）（2）（3）（6）（7）（8）	3
Kim等^[13]	回顾性	韩国	2016	FG	41	66±8.6	22/19	（1）（2）（3）（6）（7）（8）	3
Laudato等^[14]	回顾性	瑞士	2014	RA	11	65	-	（1）	2
Laudato等^[14]	回顾性	瑞士	2014	FG	48	60.7	-	（1）	2
Lonjon等^[15]	随机对照	法国	2015	RA	10	63.4±11	4/6	（1）（2）（3）（4）（5）（8）（9）	7
Lonjon等^[15]	随机对照	法国	2015	FG	10	63.4±11	4/6	（1）（2）（3）（4）（5）（8）（9）	7
Ringel等^[16]	随机对照	德国	2012	RA	30	68	14/16	（1）（2）（3）（5）（8）（9）	7
Ringel等^[16]	随机对照	德国	2012	FG	30	67	12/18	（1）（2）（3）（5）（8）（9）	7
Schizas等^[17]	随机对照	瑞士	2012	RA	11	65	6/5	（1）（4）（5）	6
Schizas等^[17]	随机对照	瑞士	2012	FG	23	66	8/15	（1）（4）（5）	6
Solomiichuk等^[18]	回顾性	瑞士	2017	RA	35	63.7±10.6	21/14	（1）（2）（3）（4）（5）（8）	3
Solomiichuk等^[18]	回顾性	瑞士	2017	FG	35	62.2±11.1	23/12	（1）（2）（3）（4）（5）（8）	3
付松等^[19]	随机对照	中国	2017	RA	24	67±4	11/13	（2）（3）（6）（7）（8）	5
付松等^[19]	随机对照	中国	2017	FG	26	69±5	12/14	（2）（3）（6）（7）（8）	5

纳入研究	类型	国家	年份	组别	例数	年龄（岁）	性别（男/女）	结局指标	改良Jadad质量评价
Hyun等^[9]	随机对照	韩国	2016	RA	30	66.5	9/21	（1）（4）（5）（6）（7）（8）（9）	7
Hyun等^[9]	随机对照	韩国	2016	FG	30	66.8	8/22	（1）（4）（5）（6）（7）（8）（9）	7
Kantelhardt等^[10]	回顾性	德国	2011	RA	55	63.1	52/60	（1）（5）（8）（9）	3
Kantelhardt等^[10]	回顾性	德国	2011	FG	57	63.1	52/60	（1）（5）（8）（9）	3
Keric等^[11]	回顾性	德国	2016	RA	66	72.3±11.1	36/30	（1）（2）（3）（5）（6）（7）（8）（9）	2
Keric等^[11]	回顾性	德国	2016	FG	24	68±11.23	13/11	（1）（2）（3）（5）（6）（7）（8）（9）	2
Kim等^[12]	随机对照	韩国	2015	RA	20	64.4±11.9	11/9	（1）（8）	6
Kim等^[12]	随机对照	韩国	2015	FG	20	64.7±8.6	8/12	（1）（8）	6
Kim等^[13]	回顾性	韩国	2016	RA	37	65.4±10.4	19/18	（1）（2）（3）（6）（7）（8）	3
Kim等^[13]	回顾性	韩国	2016	FG	41	66±8.6	22/19	（1）（2）（3）（6）（7）（8）	3
Laudato等^[14]	回顾性	瑞士	2014	RA	11	65	-	（1）	2
Laudato等^[14]	回顾性	瑞士	2014	FG	48	60.7	-	（1）	2
Lonjon等^[15]	随机对照	法国	2015	RA	10	63.4±11	4/6	（1）（2）（3）（4）（5）（8）（9）	7
Lonjon等^[15]	随机对照	法国	2015	FG	10	63.4±11	4/6	（1）（2）（3）（4）（5）（8）（9）	7
Ringel等^[16]	随机对照	德国	2012	RA	30	68	14/16	（1）（2）（3）（5）（8）（9）	7
Ringel等^[16]	随机对照	德国	2012	FG	30	67	12/18	（1）（2）（3）（5）（8）（9）	7
Schizas等^[17]	随机对照	瑞士	2012	RA	11	65	6/5	（1）（4）（5）	6
Schizas等^[17]	随机对照	瑞士	2012	FG	23	66	8/15	（1）（4）（5）	6
Solomiichuk等^[18]	回顾性	瑞士	2017	RA	35	63.7±10.6	21/14	（1）（2）（3）（4）（5）（8）	3
Solomiichuk等^[18]	回顾性	瑞士	2017	FG	35	62.2±11.1	23/12	（1）（2）（3）（4）（5）（8）	3
付松等^[19]	随机对照	中国	2017	RA	24	67±4	11/13	（2）（3）（6）（7）（8）	5
付松等^[19]	随机对照	中国	2017	FG	26	69±5	12/14	（2）（3）（6）（7）（8）	5

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