Introduction
Osteoarthritis (OA) is a chronic degenerative joint disease that comprises part of the aging process. It is characterized by the loss and degradation of articular cartilage in addition to synovial inflammation, leading to joint stiffness, swelling, and loss of mobility [
1]. It can also cause serious localized pain, deprive joint function, and eventually lead to disabilities. This leads to a high medical and economic burden on society owing to the increased proportion of the elderly population. The prevalence of OA is expected to increase by about 40%, making OA the fourth most common cause of disability worldwide in 2020 [
2,
3]. In 2010, the global age-standardized prevalence of knee OA was 3.8% [
4]. OA mainly affects the joints of the knees, hips, hands, facets, and feet, and because of the higher vulnerability of the knee to direct and indirect trauma, along with the high load supported by this joint, the knee is the joint most frequently affected by OA: previous data showed that knee OA (KOA) accounts for 83% of the total OA burden [
5]. In China, the prevalence of KOA in China was 21.51% [
6].
Understanding the risk factors for KOA is important for managing health among adults, particularly in the elderly population. Several studies investigating the risk factors for KOA have been conducted in the US, UK, and other developed countries [
7‐
9]. Moreover, some studies on KOA have been conducted in cities in China [
10,
11]. However, considering substantial differences in race, socioeconomic status, environmental factors, and lifestyle patterns, these findings have limited implications for rural populations.
The aim of this study was to investigate the prevalence and risk factors for KOA in a rural area of Tianjin China.
Patients and methods
This population-based cross-sectional study was conducted between June and August 2020. The study participants were drawn using a random cluster stratified sampling method from the resident population in the rural areas of Tianjin.
Four towns in the Jizhou District of Tianjin were randomly selected, with one village selected from each town. All participants aged at least 40 years were included in the study. Inclusion criteria were (1) age ≥ 40 years and (2) permanent resident with registered household registrations in the Jizhou District, Tianjin. Exclusion criteria were (1) age less than 40 years; (2) no local household registration; (3) unwilling to cooperate with the study or unwilling to sign an informed consent form; (4) secondary arthritis (including congenital or developmental diseases); (5) inflammatory arthritis (systemic lupus erythematosus, rheumatoid arthritis, rheumatoid arthritis, gouty arthritis, hemophilic arthritis, etc.); and (6) major mental illness.
All study protocols were approved by Chinese Ethics Committee of Registering Clinical Trials (ChiECRCT20210021), and all participants provided informed consent.
Collection of patient data
Participant information, including sex, date of birth, education level, sleep quality, and walking, was obtained from existing records. Participants were divided into four age groups: 40–55 years, 55–64 years, 65–74 years, ≥ 75 years. Educational level was divided into the following categories: illiterate, primary, elementary, high school, and college.
Definition of risk factors
Personal lifestyle characteristics, including smoking and drinking. Participants were divided into smoking, quitting, and never smoking groups by smoking status; smoking > 1 cigarette per day for at least 1 year, quitting smoking was defined as quitting smoking for at least half a year. Participants were divided into drinking, abstaining, and never drinking groups by drinking status. Drinking was defined as drinking more than 500 g per week for at least one year, abstaining was defined as quitting drinking for at least half year. Body mass index ([BMI] = weight (kg)/height [m]
2) was used as a measure of relative body weight, with BMI < 24.0 kg/m
2 defined as normal weight, 24.0 kg/m ≤ BMI < 28.0 kg/m
2 as overweight, and BMI ≥ 28.0 kg/m
2 as obese. Walking was defined as walking two miles or more at least once a week [
12].
Diagnosis of KOA
The 1995 American College of Rheumatology clinical diagnostic criteria for KOA are as follows [
13]: (1) repeated knee pain in the past month; (2) age ≥ 50 years; (3) morning stiffness ≥ 30 min; (4) crepitus on motion; and (5) radiographs (standing or weight-bearing) show joint space narrowing, subchondral sclerosis, and/or cystic degeneration, along with articular edge osteophyte formation. KOA can be diagnosed if the above criteria 1, 2, 3, and 4 are met at the same time, or if the criteria 1, 5 are met.
Statistical analysis
Continuous variables are expressed as the mean ± standard deviation. Age, years of education, BMI, and sleep duration between the two groups of men and women were tested using the independent samples T test. Categorical variables such as groups for age, BMI, education level, smoking, drinking, sleep quality, and frequent walking were tested using the chi-squared test; multivariate logistic regression analysis was used to analyze the risk factors affecting KOA. The selection criteria for the inclusion of variables in the multivariate analysis was P < 0.25 for independent variables in the univariate analysis [
14]. Adjusted variables, including sex, age, BMI, education level, smoking status, alcohol consumption, sleep status, and frequent walking, were included in the multivariate analysis of the entire population. Statistical significance was set at P < 0.05. Statistical analysis was performed using SPSS 25.0 statistical software.
Discussion
Many countries and regions have investigated the prevalence of osteoarthritis. Considering the large differences between different ethnic groups, socioeconomic status, environmental factors, and lifestyle patterns. We report the prevalence of KOA and its associated influencing factors in rural areas of Tianjin. The overall prevalence of KOA in the study population was 10.3%, and the risk of KOA in women was 1.764 times higher than in men. Moreover, the risk of KOA increased with increasing age, increasing BMI, a decline of sleep quality, and frequent walking, while the risk of KOA was lower with increased education level. In conclusion, sex, age, education level, BMI, sleep quality, and walking frequency were independent factors influencing KOA. In addition, factors influencing knee osteoarthritis exhibit sex-specific differences. For example, the risk of KOA in postmenopausal women is 4.12 times higher than that in premenopausal women.
In a Nigerian study, the prevalence of KOA was approximately 15.6 percent [
15]. In the United States, symptomatic KOA occurs in 6 percent of adults aged 30 years and older and in 10 percent of those aged over 65 years [
16,
17]. By comparison, the overall prevalence of KOA in suburban villages of Beijing, China, is approximately 9.6% [
18], and a study in Taiyuan showed a prevalence of KOA of 10.9% [
19]. The prevalence of KOA was 13.8% in the rural areas of Shanxi Province [
20], and a study of urban communities in Heilongjiang showed a prevalence of KOA of 16.1% [
10]; our study of rural areas in Tianjin showed a prevalence of KOA of 10.3%. As indicated by the data, there are differences in the prevalence of KOA between these regions; these differences may be related to differences in ethnicity, environmental factors, geography, or lifestyle. Potential biases caused by differences in research methods and demographics may also have some impact on the findings.
The current findings suggest that age is a risk factor for KOA. The prevalence of KOA gradually increased with age and was higher in women than in men. US studies similarly showed that the prevalence of KOA increases with age [
16] and that female sex is an independent risk factor for KOA [
21]. Furthermore, studies from different regions of China have shown that the prevalence of KOA increases with age, with a higher prevalence among women [
10,
19,
20]. Abnormal gait mechanics are implicated in the pathogenesis of KOA. A US study showed that knee kinematics change with age, which may be one of the reasons for the increased prevalence of KOA with age.
Studies have also suggested that kinematic measures have the potential to provide early markers for identifying the risk of developing KOA with age [
21]. Additionally, Garcia et al. observed sex differences in gait mechanics and reported that women may have greater joint loads in the medial compartment of the knee [
22]. Moreover, evidence suggests that women have altered knee loads compared with men [
23] and that sex differences in gait mechanics are one reason for the higher prevalence of KOA in women. In addition, sex differences seem to be one of the main reasons for the risk of KOA. In the present study, after adjusting for other factors, the risk of KOA in postmenopausal women was still 4.12 times that of non-menopausal women. A national study from South Korea showed that the prevalence of OA was higher in women than in men and that the incidence of OA increased significantly during menopause [
24]. Another Korean study showed that the increased incidence of postmenopausal OA may be related to female hormonal changes, and the pathogenesis may be that estrogen deficiency affects OA development [
25].
The current results also show that frequent walking behavior is an independent risk factor for KOA. With an increase in walking behavior, the prevalence of KOA increases, and frequent walking is an independent risk factor for KOA in men but not in women in our study population. Frequent walkers may have poor walking habits that can lead to long-term damage to the knee joint. A US study has shown that varus thrust during walking is common in patients with KOA and increases the risk of disease progression [
26]. However, appropriate physical exercise and correct exercise posture can reduce the prevalence of KOA. Findings from a US study suggest that maintaining physical activity in midlife may have a small but manageable impact on knee function and biomechanics, which translates into a more stable loading environment for the knee in midlife and thus reduces the risk of KOA in future years [
27].
Furthermore, a prospective study showed that obesity was an independent influencing factor for KOA [
28]. Similarly, research from the US showed that obesity may lead to KOA [
29]. Consistent with these findings, the current results show that overweight and obesity are independent risk factors for KOA. However, in the present study population, overweight and obesity were independent influencing factors for KOA in women but not in men. Combined with previous reports, it is speculated that obesity may exert a heavier pressure load on the knee joint compared to normal weight, resulting in a higher prevalence of KOA; however, prospective studies are still needed to determine the impact of a higher load on KOA.
After adjusting for other influencing factors, education level was an independent influencing factor for KOA, and participants with elementary level had the lowest prevalence of KOA. The results of the Korean study showed that lower educational attainment was associated with KOA prevalence and symptoms, indicating that improving socio-educational levels may reduce the socioeconomic burden of KOA [
30]. In addition, the results of a meta-analysis showed that educational level can improve the quality-of-life of KOA patients [
31]. The reasons for the strong relationship between educational attainment and prevalence of KOA and knee pain are currently unclear, and some unmeasured confounders may have influenced the results.
The prevalence of nocturnal knee pain and sleep problems increases with OA severity, affecting the patients' quality of life [
32]. US studies have shown that better sleep quality is associated with reduced knee pain exacerbation [
33]. Another US study showed an association between poor sleep and KOA symptoms [
34]. Our study found that sleep quality was associated with the prevalence of KOA in both men and women. Although the current analysis of cross-sectional data supports an association between sleep quality and KOA prevalence, this association has not been demonstrated in longitudinal studies. Further research is required to examine the relationship between sleep quality and KOA prevalence.
This study had several limitations. First, this was a cross-sectional study, and we could not clarify any causal relationship between influencing factors in the occurrence and development of KOA. Second, sleep quality was self-reported by the participants through questionnaire and this instrument does not have psychometric properties. Smoking was initially classified into three categories: ever smoker, former smoker, and never smoker. No exposure quantification method was used to adequately summarize a particular individual's smoking history. This may have an impact on the analysis of the factors influencing KOA. Alcohol consumption is similar to that of smoking. In addition, there were no imaging diagnoses in our study, which may have contributed to the decreased prevalence of KOA reported in the text. Finally, some KOA-relative factors, which included sleep conditions, labor intensity, preached cognition, dietary habits, knee related exercise conditions, sun exposure, blood pressure, blood lipid, blood glucose situation and other influence circulating metabolic factors, were lacking in this study. We will continue to monitor the prevalence of KOA among participants in the region in the future. Future studies should include X-ray or MRI examinations to further clarify the causal relationship between KOA influencing factors and KOA prevalence.
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.