距放大装置的距离导致 TSF 矫正患者下肢长度的测量值存在差异。

Distance from the magnification device contributes to differences in lower leg length measured in patients with TSF correction.

机构信息

Department of Traumatology and Reconstructive Surgery, BG Trauma Center Tübingen, Eberhard-Karls University of Tübingen, Schnarrenberg-Str. 95, 72076, Tübingen, Germany.

AO Research Institute Davos, Davos, Switzerland.

出版信息

Arch Orthop Trauma Surg. 2022 Jul;142(7):1511-1522. doi: 10.1007/s00402-021-03831-1. Epub 2021 Mar 6.

DOI:10.1007/s00402-021-03831-1

PMID:33674962

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9217775/

Abstract

INTRODUCTION

In absence of deformity or injury of the contralateral leg, the contralateral leg length is used to plan limb lengthening. Length variability on long-leg weight-bearing radiographs (LLR) can lead to inaccurate deformity correction. The aim of the study was to (1) examine the variability of the measured limb length on LLR and (2) to examine the influence of the position of the magnification device.

MATERIALS AND METHODS

The limb lengths of 38 patients during deformity correction with a taylor-spatial-frame were measured retrospectively on 7.3 ± 2.6 (4-13) LLR per patient. The measured length of the untreated limb between LLR were used to determine length variability between LLR in each patient. To answer the secondary aim, we took LLR from a 90 cm validation distance. A magnification device was placed in different positions: at the middle of the 90 cm distance (z-position), 5 cm anterior and 5 cm posterior from the z-position, at the bottom and top of the validation distance as well as 5 cm medial and 15 cm lateral from the z-position.

RESULTS

The measured length variability ranged within a patient from 10 to 50 mm. 76% of patients had a measured limb length difference of ≥ 2 cm between taken LLR. Compared to length measurement of the 90 cm test object with the magnification device in the z-position (90.1 cm), positioning the device 5 cm anterior led to smaller (88.6 cm) and 5 cm posterior led to larger measurements (91.7 cm). The measured length with the magnification device at the bottom, top, medial or lateral (90.4; 89.9; 90.2; 89.8 cm) to the object differed not relevantly.

CONCLUSIONS

High variability of limb length between different LLR within one patient was observed. This can result from different positions of the magnification device in the sagittal plane. These small changes in positioning the device should be avoided to achieve accurate deformity correction and bone lengthening. This should be considered for all length and size measurements on radiographs.

摘要

引言

在对健侧肢体没有畸形或损伤的情况下，会使用健侧肢体的长度来规划肢体延长。在长肢负重 X 线片（LLR）上的长度变化可能会导致不准确的畸形矫正。本研究的目的是：（1）检查 LLR 上测量的肢体长度的可变性；（2）检查放大设备位置的影响。

材料和方法

回顾性分析了 38 例接受泰勒空间框架矫形的患者的肢体长度，每位患者的 LLR 数量为 7.3±2.6（4-13）张。用未治疗肢体的 LLR 之间的测量长度来确定每位患者的 LLR 之间的长度变化。为了回答次要目标，我们在 90cm 的验证距离处拍摄了 LLR。在不同位置放置了一个放大设备：在 90cm 距离的中间（z 位置）、z 位置前后 5cm、底部和顶部以及 z 位置内侧 5cm 和外侧 15cm。

结果

患者内的测量长度变化范围为 10-50mm。76%的患者在拍摄的 LLR 之间的测量肢体长度差异≥2cm。与在 z 位置（90.1cm）用放大设备测量 90cm 测试物体的长度相比，将设备放置在前方 5cm 处会导致更小的测量值（88.6cm），而放置在后方 5cm 处会导致更大的测量值（91.7cm）。在物体底部、顶部、内侧或外侧用放大设备测量的长度（90.4cm、89.9cm、90.2cm、89.8cm）与物体无明显差异。

结论

观察到同一患者不同 LLR 之间的肢体长度变化很大。这可能是由于在矢状面上放大设备的位置不同所致。为了实现准确的畸形矫正和骨骼延长，应避免设备位置的这些微小变化。这应考虑到所有 X 线片上的长度和尺寸测量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2b6c/9217775/a0da3e9f2819/402_2021_3831_Fig1_HTML.jpg

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距放大装置的距离导致 TSF 矫正患者下肢长度的测量值存在差异。

Distance from the magnification device contributes to differences in lower leg length measured in patients with TSF correction.

机构信息

出版信息

INTRODUCTION

MATERIALS AND METHODS

RESULTS

CONCLUSIONS

引言

材料和方法

结果

结论

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