Letter to the Editor

IF 1.6 4区医学 Q2 PEDIATRICS

Journal of paediatrics and child health Pub Date : 2024-10-17 DOI:10.1111/jpc.16700

Mr Jack Ho, Ms Lena Lim, Mr Leonardo Bruzze, Ms Ailsa Marshall, Ms Amelia Christie, Ms Sandeep Kaur, Dr Nghi Bui, Ms Gillian Burke, Ms Sharon Youde, Dr Kim Ramjan, Dr Amy Wanaguru, Dr Ohn Nyunt, Prof Charles Verge, Prof Shihab Hameed

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引用次数: 0

Abstract

Continuous glucose monitoring (CGM) measures interstitial glucose levels up to 1440 times per day, providing vastly more information to guide insulin dosing than fingerstick blood glucose levels. Another technological improvement has been the availability of algorithm-driven insulin pumps, which can now automatically deliver insulin to correct high-glucose levels and suspend insulin delivery to prevent hypoglycaemia. These pumps, known as advanced hybrid closed-loop (AHCL) systems, substantially reduce the need for manual intervention, but still require effort from patients to accurately enter the amount of carbohydrates they are consuming. Furthermore, AHCL systems are complex, requiring detailed education by a multidisciplinary team for successful use.¹ Insulin pumps are not publicly funded in Australia. Data on the long-term clinical impact of CGM and AHCL in real-world paediatric settings are limited.^{2, 3}

We compared 2016–2021 CGM data from our metropolitan paediatric type 1 diabetes clinic to our data from 2021–2024, including the proportion meeting International Consensus guidelines⁴ (see Table 1). We also recorded HbA1c, height, weight, body mass index, clinic attendance and median income of postcode (Australian Taxation Office 2019–2020). We calculated CGM measures using Python (Python Software Foundation, Beaverton, OR, USA) and used SPSS (version 27) (IBM, Armonk, NY, USA) to perform descriptive analysis and to determine the relationship between clinical characteristics and glycaemic outcomes.

Overall, 10% of participants met every consensus target in 2021–2024, compared to 4% in 2016–2021. Rates of achieving specific targets improved modestly from 2016–2021 to 2021–2024 irrespective of diabetes therapy. Of note, the median (interquartile range) CGM usage-time improved from 88% (72–95) in 2016–2021 to 95% (82–97) in 2021–2024 (P < 0.001). Multiple linear regression revealed that CGM usage-time (P < 0.001) and clinic attendance percentage (P = 0.008) were significant predictors of time in range (TIR) for the 2016–2021 cohort (adjusted R² for overall model 0.138). For AHCL users in the 2021–2024 cohort, CGM usage-time remained the most significant predictor of TIR (P < 0.001), followed by median yearly income of postcode (P = 0.030, adjusted R² 0.167). An increase in AU$10k in median income was associated with an absolute increase of 3.7% TIR. Sex, body mass index and pump use did not predict TIR.

The proportion of patients meeting International Consensus criteria has improved in recent years but remains low and further improvements are needed. Consistent use of CGM is clinically important. Children living in suburbs with higher median incomes had higher TIR. Ensuring access to these vital technologies remains a high priority, with an important advocacy role for all those involved in the care of children and adolescents with diabetes.

The study was performed in accordance with the principles of the Declaration of Helsinki, the International Council for Harmonisation of Good Clinical Practice guidelines. All individual data have been de-identified and aggregated. The protocol was approved by the Northern Sydney Local Health District Human Research Ethics Committee (2020/ETH01325). The protocol was designed and completed independently by the investigators, without any input from pharmaceutical or medical diagnostic corporations. All authors contributed to the publication and reviewed the manuscript.

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致编辑的信

连续血糖监测（CGM）每天可测量间质葡萄糖水平达1440次，为指导胰岛素剂量提供了比指测血糖水平多得多的信息。另一项技术进步是算法驱动的胰岛素泵的可用性，它现在可以自动输送胰岛素来纠正高血糖水平，并暂停胰岛素输送以防止低血糖。这些泵，被称为先进的混合闭环（AHCL）系统，大大减少了人工干预的需要，但仍然需要患者努力准确地输入他们消耗的碳水化合物量。此外，AHCL系统是复杂的，需要多学科团队的详细培训才能成功使用在澳大利亚，胰岛素泵不是由政府资助的。关于CGM和AHCL在现实儿科环境中的长期临床影响的数据有限。2,3我们比较了2016-2021年大都市儿科1型糖尿病诊所的CGM数据与2021-2024年的数据，包括符合国际共识指南的比例4（见表1）。我们还记录了HbA1c、身高、体重、体重指数、诊所出诊率和邮编收入中位数（澳大利亚税务局2019-2020）。我们使用Python （Python Software Foundation, Beaverton， OR， USA）计算CGM测量值，并使用SPSS (version 27) （IBM, Armonk， NY， USA）进行描述性分析并确定临床特征与血糖结局之间的关系。总体而言，10%的参与者在2021-2024年实现了所有共识目标，而2016-2021年为4%。无论糖尿病治疗如何，2016-2021年至2021-2024年期间实现特定目标的比率略有提高。值得注意的是，CGM使用时间的中位数（四分位数范围）从2016-2021年的88%（72-95）提高到2021-2024年的95% (82-97)（P < 0.001）。多元线性回归显示，CGM使用时间（P < 0.001）和诊所出勤率（P = 0.008）是2016-2021年队列中值域时间（TIR）的显著预测因子（整体模型调整R2为0.138）。对于2021-2024年队列的AHCL用户，CGM使用时间仍然是TIR的最显著预测因子（P < 0.001），其次是邮编年收入中位数（P = 0.030，调整R2 0.167）。收入中位数每增加1万澳元，TIR绝对增长3.7%。性别、身体质量指数和泵的使用不能预测TIR。近年来，符合国际共识标准的患者比例有所改善，但仍然很低，需要进一步改善。持续使用CGM在临床上很重要。居住在收入中位数较高的郊区的孩子的TIR更高。确保获得这些至关重要的技术仍然是一个高度优先事项，所有参与照顾糖尿病儿童和青少年的人都可以发挥重要的宣传作用。这项研究是按照赫尔辛基宣言的原则进行的，国际良好临床实践协调委员会的指导方针。所有个人数据都已去识别并汇总。该方案已获得北悉尼地方卫生区人类研究伦理委员会（2020/ETH01325）的批准。该议定书是由调查人员独立设计和完成的，没有任何制药或医疗诊断公司的投入。所有作者都为出版物做出了贡献并审阅了手稿。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of paediatrics and child health 医学-小儿科

CiteScore

2.90

自引率

5.90%

发文量

487

审稿时长

3-6 weeks

期刊介绍： The Journal of Paediatrics and Child Health publishes original research articles of scientific excellence in paediatrics and child health. Research Articles, Case Reports and Letters to the Editor are published, together with invited Reviews, Annotations, Editorial Comments and manuscripts of educational interest.