Keywords:
COVID-19; cohort studies; computerized medical record systems; diabetes; glycemic control; monitoring; primary health care; type 2 diabetes mellitus
The COVID-19 pandemic and recommended social distancing and other nonpharmaceutical interventions have had a substantial impact on primary care services in the United Kingdom [1,2]. Face-to-face consultations were markedly reduced, and primary care appointments decreased by 64.6% and home visits decreased by 62.6% from the week commencing March 9, 2020, coinciding with national policy changes [3]. This was a consequence of lockdown restrictions and changes made by a series of scientific advisory groups to minimize the risk of exposure to COVID-19, which included encouraging telemedicine as the preferred alternative for face-to-face consultations [1,4]. During the initial stages of the pandemic, primary care services reserved face-to-face consultations for priority appointments, while the policy for delivering routine care via telemedicine was adopted [1]. The changes in methods of consultation and interrupted routine care may have adversely affected the management of people with type 2 diabetes mellitus (T2DM) [5].Previous studies have identified that missed hemoglobin A1c (HbA1c) monitoring appointments is associated with higher HbA1c [6,7]. A recent study showed a 40% reduction in HbA1c testing during the first year of the COVID-19 pandemic compared to the preceding year [8]. It is well established that impaired glycemic control is associated with the increased risk of micro- and macrovascular complications [8,9], indicating the benefit to people with T2DM having regular HbA1c monitoring.In 2014, the National Institute for Health and Care Excellence (NICE) introduced clinical guidelines for its Quality and Outcomes Framework (QOF) indicator menu to encourage regular monitoring and management of diabetes [10,11]. These are known as routine annual reviews, which include eight health checks: HbA1c, blood pressure, cholesterol, serum creatinine, urine albumin, foot surveillance, BMI, and smoking status [11]. The proposed indicators are based on the best evidence and are implemented to provide high standards of care and improved results for patients.However, the extent to which interruptions in primary care services (eg, face-to-face appointments) affected the monitoring of people with T2DM in the United Kingdom during the COVID-19 pandemic has yet to be established. This protocol describes our planned methods to explore the impact of the pandemic on the monitoring of people with T2DM in a UK-based setting.
Aims and Objectives
Our primary objective is to assess the impact of the COVID-19 pandemic on HbA1c monitoring in people with T2DM. As a secondary objective, we will explore changes in the rates of routine annual reviews between the pre–COVID-19 pandemic period and during the first year of the COVID-19 pandemic.
Methods
Study Design
We will conduct a retrospective cohort analysis using observational data of adults with T2DM from the Oxford-Royal College of General Practitioners (RCGP) Research and Surveillance Centre (RSC) sentinel network database. The study cohort will be observed at two time points: the year preceding the COVID-19 pandemic (January 1 to December 31, 2019) and the first year of the COVID-19 pandemic (January 1 to December 31, 2020).
Data Source
The Oxford-RCGP RSC is a sentinel network of volunteer primary care practices across England and Wales, currently comprising more than 15 million patients registered with over 1800 affiliated practices [12]. Pseudonymized coded clinical practice data is uploaded and available in near real time within a secure network, supporting the RSC’s influenza surveillance, identification of epidemics, and other research activity. The network provides a broadly representative sample of the national population [13].UK primary care data is registration based (ie, patients have unique identifiers—National Health Service [NHS] numbers). Patient electronic health care records are coded using the Systematized Nomenclature of Medicine Clinical Terms (SNOMED CT) code system, a machine-readable clinical vocabulary offering a high degree of granularity and linkage to other classifications and international terminologies [14]. Most of the T2DM management occurs in primary care and pay-for-performance targets to incentivize chronic disease management including T2DM, resulting in well-maintained disease registries, thus ensuring high-quality data for this study [5,15,16].
Study Population
We will identify adults (aged ≥18 years) with T2DM using diagnosis codes. The cohort for this study will comprise individuals diagnosed with T2DM on or before December 31, 2018, and who are registered with an Oxford-RCGP RSC practice on this date.
Exposure
The exposure variable will be binary to indicate the first calendar year of the COVID-19 pandemic (January 1 to December 31, 2020) and the year before the pandemic (January 1 to December 31, 2019).
Outcomes
Our primary outcome measure will be the rate of HbA1c monitoring in the year 2020; this will be compared to HbA1c monitoring in the preceding year.The secondary outcome will be a measure of the NICE eight health checks that make up the routine annual review in each study period. We will sum the number of types of checks conducted in the year per patient and code this to an ordinal variable (≤5 care processes, 6-7 care processes, 8 care processes).
Study Variables
The study variables of interest are divided into personal characteristics and practice characteristics.
Personal Characteristics
The following personal characteristics will be used: age (treated as a continuous variable), gender (male or female), socioeconomic status (quintiles of the Index of Multiple Deprivation [IMD]) according to the national distribution of IMD scores based on the postal code of the patient [17], ethnicity (categorized into major ethnic groups, defined by the Office of National Statistics, Asian, Black, Mixed, White, or other ethnic group) [18,19], COVID-19 shielding status, duration of diabetes, and presence of comorbidities (eg, hypertension and chronic kidney disease; determined by diagnosis codes).
Practice Characteristics
For the practice characteristics, urban versus rural primary care practices will be identified from the practice Lower Layer Super Output Area. The practice size, QOF linkage, NHS region (East of England, London, Midlands, North East and Yorkshire, North West, South East, South West), and the number/type of consultations will be taken into account [20].
Statistical Analysis
The summary statistics will be reported as counts and percentages for categorical data and means (with SDs) for continuous data.If the missing data is <5% (as routine primary care data is incomplete, we anticipate a small degree of missing data in most, if not all, covariates), no attempt will be made to impute the missing values. Missing data >5% will be handled through multiple imputation by chained equations using the MICE package, version 3.14.0 [21].To assess the impact of the COVID-19 pandemic on HbA1c monitoring, we will estimate the odds ratio of HbA1c monitoring during the pandemic period and the pre–COVID-19 pandemic period in a multilevel logistic regression model with the first COVID-19 year as an indicator variable. The random intercept model will enable the variation of the impact of the pandemic at the patient, GP, and geographical level to be assessed and enable the estimation of robust effect sizes. We will use ancillary analyses to estimate the population-level effects of covariates measured at the patient and practice level to better describe the impact of interpractice variation.The secondary outcome, measuring the degree to which patients received all eight routine annual review checks, will be modeled using a mixed effects ordinal regression, adding random effects at the practice level. Current research has shown variation in the attainment of the individual checks. We will describe the attainment of the individual checks and achievement of all eight checks. We will adopt the methods used by Holman et al [22] and define the secondary outcome measure as an aggregate score of the varying degrees of partial attainment with an explicit natural ordering. This secondary outcome measure will then be modeled using mixed effects ordinal regression adding random effects at the practice level, accounting for the ranking of the levels of attainment.The data analysis will be carried out using the statistical software, R version 4.1.1 (The R Foundation for Statistical Computing) [23].
Ethical Considerations
Research ethics approval (Reference R77306/RE001) was obtained from the University of Oxford Medical Sciences Interdivisional Research Ethics Committee in September 2021. Data are pseudonymized at the point of data extraction and will be held on a secure network at the University of Oxford. This network is compliant with NHS Digital Data Security and Protection toolkit standards [24]. The data analysis will begin in November 2021.
Results
A power calculation has been made, based on a Z test, for the study. A study with an effect size of 0.05 (1% change in monitoring rates) and at a power of 75% will require a total sample size of 237,026 people with T2DM. The power calculation was carried out using G*Power 3.1.9.7 (Buchner A).The analysis of the data extracted will include 3.96 million patients with T2DM across 700 practices, which is 6% of the available Oxford-RCGP RSC adult population. The preliminary results will be submitted for presentation at a primary care–themed conference. The resulting publication will be submitted for publication in a peer-reviewed journal.
Discussion
Overview
This protocol describes how we will explore the effect of the COVID-19 pandemic on the monitoring of people with T2DM by sociodemographics and other individual clinical characteristics. The Oxford-RCGP RSC database is appropriate to use, as the majority of the people with T2DM are managed in primary care.It is valuable to study primary care practices with respect to diabetes monitoring during the pandemic using evidence-based research. People with T2DM require regular monitoring to minimize the risk of diabetes-associated complications. However, changes in the delivery of primary care services as a result of the COVID-19 pandemic has brought challenges in T2DM assessment and monitoring [2]. The existing literature has focused on an unprecedented reorganization of UK primary care during the pandemic [3]. Remote monitoring systems proved to be feasible and were supported by the current clinical guidelines [3]. However, the study results might represent a considerable burden of unmet need, validating the results of other studies [2,8].
Strengths and Limitations
The Oxford-RCGP RSC is a large network of primary care practices with wide coverage. Although the network covers England and Wales, previous literature has reported that it provides a representative sample of the UK population, and hence, the final results will be broadly generalizable to the United Kingdom as a whole [13]. Furthermore, the quality of computerized medical records is high due to pay-for-performance targets [15].However, there are several limitations. Being routinely collected data, there may be issues of missingness and inaccurate recordings. This will be accounted for by using multiple imputation. Moreover, since this is an observational study, one limitation will be unmeasured confounding factors that may result in biased effect estimates, which we will mitigate by performing a sensitivity analysis. Additionally, the enrollment of practices depends on the types of ongoing projects and clinical trials; therefore, our identification of practices will vary. They are signed up to the Oxford-RCGP RSC network on a voluntary basis, which may cause a higher representation of the more affluent areas compared to the average national population [13]. Any additional strengths and limitations observed during the study will be reported in the final manuscript.
Conclusion
This study will provide insight into the impact of the pandemic in the monitoring of NICE routine annual reviews of people with T2DM managed in an English primary care setting. We expect the outcomes from this study to highlight the need for “catch up” in order for primary care to enhance best practices and prevent T2DM complications.
Authors: Naomi Holman; Peter Knighton; Jackie OʼKeefe; Sarah H Wild; Sarah Brewster; Hermione Price; Kiran Patel; Wasim Hanif; Vinod Patel; Edward W Gregg; Richard I G Holt; Roger Gadsby; Kamlesh Khunti; Jonathan Valabhji; Bob Young; Naveed Sattar Journal: Diabetes Obes Metab Date: 2021-09-01 Impact factor: 6.577
Authors: Andrew J Karter; Melissa M Parker; Howard H Moffet; Ameena T Ahmed; Assiamira Ferrara; Jennifer Y Liu; Joe V Selby Journal: Med Care Date: 2004-02 Impact factor: 2.983
Authors: F D Richard Hobbs; Clare Bankhead; Toqir Mukhtar; Sarah Stevens; Rafael Perera-Salazar; Tim Holt; Chris Salisbury Journal: Lancet Date: 2016-04-05 Impact factor: 79.321
Authors: Mark Joy; Dylan McGagh; Nicholas Jones; Harshana Liyanage; Julian Sherlock; Vaishnavi Parimalanathan; Oluwafunmi Akinyemi; Jeremy van Vlymen; Gary Howsam; Martin Marshall; Fd Richard Hobbs; Simon de Lusignan Journal: Br J Gen Pract Date: 2020-07-30 Impact factor: 5.386
Authors: Ana Correa; William Hinton; Andrew McGovern; Jeremy van Vlymen; Ivelina Yonova; Simon Jones; Simon de Lusignan Journal: BMJ Open Date: 2016-04-20 Impact factor: 2.692
Authors: Kathryn E Mansfield; Rohini Mathur; John Tazare; Alasdair D Henderson; Amy R Mulick; Helena Carreira; Anthony A Matthews; Patrick Bidulka; Alicia Gayle; Harriet Forbes; Sarah Cook; Angel Y S Wong; Helen Strongman; Kevin Wing; Charlotte Warren-Gash; Sharon L Cadogan; Liam Smeeth; Joseph F Hayes; Jennifer K Quint; Martin McKee; Sinéad M Langan Journal: Lancet Digit Health Date: 2021-02-18