Machine learning identifies clusters of the normal adolescent spine based on sagittal balance.

IF 1.6 Q3 CLINICAL NEUROLOGY

Spine deformity Pub Date : 2024-08-21 DOI:10.1007/s43390-024-00952-6

Dion G Birhiray, Srikhar V Chilukuri, Caleb C Witsken, Maggie Wang, Jacob P Scioscia, Martin Gehrchen, Lorenzo R Deveza, Benny Dahl

{"title":"Machine learning identifies clusters of the normal adolescent spine based on sagittal balance.","authors":"Dion G Birhiray, Srikhar V Chilukuri, Caleb C Witsken, Maggie Wang, Jacob P Scioscia, Martin Gehrchen, Lorenzo R Deveza, Benny Dahl","doi":"10.1007/s43390-024-00952-6","DOIUrl":null,"url":null,"abstract":"Purpose: This study applied a machine learning semi-supervised clustering approach to radiographs of adolescent sagittal spines from a single pediatric institution to identify patterns of sagittal alignment in the normal adolescent spine. We sought to explore the inherent variability found in adolescent sagittal alignment using machine learning to remove bias and determine whether clusters of sagittal alignment exist.Methods: Multiple semi-supervised machine learning clustering algorithms were applied to 111 normal adolescent sagittal spines. Sagittal parameters for resultant clusters were determined.Results: Machine learning analysis found that the spines did cluster into distinct groups with an optimal number of clusters ranging from 3 to 5. We performed an analysis on both 3 and 5-cluster groups. The 3-cluster groups analysis found good consistency between methods with 96 of 111, while the analysis of 5-cluster groups found consistency with 105 of 111 spines. When assessing for differences in sagittal parameters between the groups for both analyses, there were differences in T4-12 TK, L1-S1 LL, SS, SVA, PI-LL mismatch, and TPA. However, the only parameter that was statistically different for all groups was SVA.Conclusions: Based on machine learning, the adolescent sagittal spine alignments do cluster into distinct groups. While there were distinguishing features with TK and LL, the most important parameter distinguishing these groups was SVA. Further studies may help to understand these findings in relation to spinal deformities.","PeriodicalId":21796,"journal":{"name":"Spine deformity","volume":null,"pages":null},"PeriodicalIF":1.6000,"publicationDate":"2024-08-21","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Spine deformity","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1007/s43390-024-00952-6","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"CLINICAL NEUROLOGY","Score":null,"Total":0}

引用次数: 0

Abstract

Purpose: This study applied a machine learning semi-supervised clustering approach to radiographs of adolescent sagittal spines from a single pediatric institution to identify patterns of sagittal alignment in the normal adolescent spine. We sought to explore the inherent variability found in adolescent sagittal alignment using machine learning to remove bias and determine whether clusters of sagittal alignment exist.

Methods: Multiple semi-supervised machine learning clustering algorithms were applied to 111 normal adolescent sagittal spines. Sagittal parameters for resultant clusters were determined.

Results: Machine learning analysis found that the spines did cluster into distinct groups with an optimal number of clusters ranging from 3 to 5. We performed an analysis on both 3 and 5-cluster groups. The 3-cluster groups analysis found good consistency between methods with 96 of 111, while the analysis of 5-cluster groups found consistency with 105 of 111 spines. When assessing for differences in sagittal parameters between the groups for both analyses, there were differences in T4-12 TK, L1-S1 LL, SS, SVA, PI-LL mismatch, and TPA. However, the only parameter that was statistically different for all groups was SVA.

Conclusions: Based on machine learning, the adolescent sagittal spine alignments do cluster into distinct groups. While there were distinguishing features with TK and LL, the most important parameter distinguishing these groups was SVA. Further studies may help to understand these findings in relation to spinal deformities.

查看原文本刊更多论文

机器学习根据矢状平衡识别正常青少年脊柱群。

目的：本研究对来自一家儿科机构的青少年矢状脊柱X光片采用机器学习半监督聚类方法，以确定正常青少年脊柱的矢状对齐模式。我们试图利用机器学习来消除偏差，并确定是否存在矢状排列集群，从而探索青少年矢状排列的内在可变性：方法：将多种半监督机器学习聚类算法应用于 111 个正常青少年矢状脊柱。结果：机器学习分析发现，脊柱的矢状面对齐度较低，而脊柱的矢状面对齐度较高：结果：机器学习分析发现，脊柱确实聚类成不同的组，最佳聚类数为 3 至 5 个。我们对 3 簇和 5 簇进行了分析。3 簇分组分析发现，111 个脊柱中有 96 个与 3 簇分组分析结果一致，而 5 簇分组分析发现，111 个脊柱中有 105 个与 5 簇分组分析结果一致。在评估两组分析的矢状面参数差异时，T4-12 TK、L1-S1 LL、SS、SVA、PI-LL 错位和 TPA 存在差异。然而，所有组别中唯一存在统计学差异的参数是 SVA：结论：基于机器学习，青少年矢状脊柱排列确实分为不同的组别。虽然 TK 和 LL 有不同的特征，但区分这些组别的最重要参数是 SVA。进一步的研究可能有助于理解这些发现与脊柱畸形的关系。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Spine deformity

CiteScore

3.20

自引率

18.80%

发文量

167

期刊介绍： Spine Deformity the official journal of the?Scoliosis Research Society is a peer-refereed publication to disseminate knowledge on basic science and clinical research into the?etiology?biomechanics?treatment?methods and outcomes of all types of?spinal deformities. The international members of the Editorial Board provide a worldwide perspective for the journal's area of interest.The?journal?will enhance the mission of the Society which is to foster the optimal care of all patients with?spine?deformities worldwide. Articles published in?Spine Deformity?are Medline indexed in PubMed.? The journal publishes original articles in the form of clinical and basic research. Spine Deformity will only publish studies that have institutional review board (IRB) or similar ethics committee approval for human and animal studies and have strictly observed these guidelines. The minimum follow-up period for follow-up clinical studies is 24 months.