ABSTRACT

INTRODUCTION

Depressive symptoms are common in patients with chronic kidney disease (CKD), with a prevalence of 23–29% among patients with end-stage kidney disease (ESKD) [1, 2]. Previous studies have shown that depressive symptoms are associated with adverse health outcomes in patients with ESKD. A meta-analysis found that patients with depressive symptoms have a 1.5 times higher risk of mortality [3] and several other studies found comparable results regarding other clinical outcomes (e.g. hospitalization) [4–9]. The effect of depressive symptoms has also been explored in patients with advanced CKD not receiving dialysis, but not as extensively as in patients with ESKD. Earlier studies in this population show that depressive symptoms are associated with a higher rate of adverse outcomes [10–12]. However, these studies were conducted in small cohorts, with heterogeneous results [10–12]. Additionally, literature suggests that associations between depressive symptoms and adverse outcomes are stronger in men than in women on dialysis [13, 14]. To the best of our knowledge, no studies have been conducted to investigate whether this relationship indeed differs depending on sex in patients with advanced CKD.

It is of great importance to identify modifiable factors, such as depressive symptoms, affecting decline in kidney function. If depressive symptoms affect decline in kidney function indeed, adequate treatment of depressive symptoms may be used to impede disease progression and delay dialysis initiation in CKD patients. This is especially important because, once dialysis is initiated, health-related quality of life (HRQOL) deteriorates [15] and patients are exposed to dialysis-related health risks [16]. Specifically in older patients, maintaining HRQOL, rather than prolonging life, is emphasized during the decision process of initiating dialysis or starting conservative management [17]. Thus, considering the association between depressive symptoms and HRQOL [18, 19], it is particularly important to focus on depressive symptoms and associated outcomes of older patients with advanced CKD.

Taken together, this study aims to investigate associations between depressive symptoms and adverse outcomes in older patients with advanced CKD during nephrology care. The adverse outcomes studied include disease progression towards ESKD (i.e. decline in kidney function and time to dialysis initiation) and all-cause mortality. Second, this study aims to investigate whether these relationships differ depending on sex. It was hypothesized that depressive symptoms would be associated with faster disease progression and higher mortality, and that these associations would be stronger in men than in women [10–14].

MATERIALS AND METHODS

RESULTS

Baseline characteristics

Data were available from 1708 patients. Out of those, 1326 patients (78%) completed at least three out of five mental health questions at baseline and were included. There were no clinically relevant differences in baseline characteristics between patients with and without missing values.

Table 1 describes baseline characteristics for all patients, also stratified by presence of depressive symptoms (mental health score ≤70). Depressive symptoms were reported by 515 patients (39%), with median [interquartile range (IQR)] score of 56 (46–64), which was 88 (80–92) in patients without depressive symptoms. Compared with patients without depressive symptoms, patients with depressive symptoms were more often women (P < 0.001) and had more comorbidity (P = 0.002). Patients with depressive symptoms had more often a history of psychiatric disease (P < 0.001), particularly depression. Mean baseline eGFR was 18.8 mL/min/1.73 m², with no difference between patients with and without depressive symptoms (P = 0.2). Overall eGFR decline in all patients was –0.12 mL/min/1.73 m²/month (95% CI –0.14 to –0.10). Median number of eGFR measurements was 2 (IQR 1–4), and 930 (70.1%) patients had one or more follow-up measurements in addition to their baseline measurement. An overview of baseline eGFR and all outcomes (both decline in kidney function and adverse clinical outcomes) analysed per group (with and without depressive symptoms; men and women) is shown in Table 2.

Table 1.

Baseline characteristics of all patients, and stratified by patients with and without depressive symptoms

	All patients	No depressive symptoms	Depressive symptoms
	(N = 1326)	(N = 811; 61%)	(N = 515; 39%)	P-value
Demographic data
Male sex, N (%)	883 (66.6)	588 (72.5)	295 (57.3)	<0.001
Age	75.74 ± 6.72	75.60 ± 6.64	75.97 ± 6.84	0.339
Country, N (%)				<0.001
Germany	138 (10.4)	85 (10.5)	53 (10.3)
Italy	311 (23.5)	140 (17.3)	171 (33.2)
The Netherlands	201 (15.2)	133 (16.4)	68 (13.2)
Poland	51 (3.8)	30 (3.7)	21 (4.1)
Sweden	292 (22.0)	212 (26.1)	80 (15.5)
UK	333 (25.1)	211 (26.0)	122 (23.7)
Ethnicity, N (%)a,b				0.204
White	1282 (96.7)	787 (97.0)	495 (96.1)
Black	12 (0.9)	4 (0.5)	8 (1.6)
Asian	10 (0.8)	7 (0.9)	3 (0.6)
Mixed	4 (0.3)	3 (0.4)	1 (0.2)
Level of education, N (%)a,c				<0.001
No education	28 (2.1)	7 (0.9)	21 (4.1)
Low education	363 (27.4)	190 (23.4)	173 (33.6)
Intermediate education	660 (49.8)	432 (53.3)	228 (44.3)
High education	181 (13.7)	129 (15.9)	52 (10.1)
Marital status, N (%)a				0.080
Married or living with partner	834 (62.9)	533 (65.7)	301 (58.4)
Divorced or separated	92 (6.9)	53 (6.5)	39 (7.6)
Widowed or partner has died	313 (23.6)	175 (21.6)	138 (26.8)
Never married/lived with partner	51 (3.8)	31 (3.8)	20 (3.9)
Smoking status, N (%)a,d	853 (64.3)	550 (67.8)	303 (58.8)	0.004
Clinical data
Primary kidney disease, N (%)a,e				<0.001
Glomerular disease	125 (9.4)	94 (11.6)	31 (6.0)
Diabetes	266 (20.1)	148 (18.2)	118 (22.9)
Hypertension	472 (35.6)	310 (38.2)	162 (31.5)
Other causes of kidney failuref	244 (18.4)	140 (17.3)	104 (20.2)
Comorbidity, N (%)
Diabetes mellitusa	535 (40.3)	306 (37.7)	229 (44.5)	0.013
Cerebrovascular diseasea.g	195 (14.7)	120 (14.8)	75 (14.6)	0.599
Cardiac diseasea,h	582 (43.9)	340 (41.9)	242 (47.0)	0.951
Peripheral vascular diseasea	218 (16.4)	123 (15.2)	95 (18.4)	0.093
Malignancya,i	275 (20.7)	163 (20.1)	112 (21.7)	0.394
Lung diseasea,j	202 (15.2)	112 (13.8)	90 (17.5)	0.067
BMI, kg/m2 a	28.26 ± 5.32	28.09 ± 4.87	28.54 ± 5.96	0.148
Nutritional status (SGA score)a,k
Severely malnourished (1–2)	10 (0.8)	3 (0.4)	7 (1.4)	<0.001
Moderately malnourished (3–5)	328 (24.7)	169 (20.8)	159 (30.9)
Normal nutritional status (6–7)	851 (64.2)	564 (69.5)	287 (55.7)
CCIa,l	7.12 ± 1.86	6.99 ± 1.80	7.32 ± 1.95	0.002
eGFR (1.73 mL/min/m2)a,m	18.80 ± 5.44	18.95 ± 5.21	18.58 ± 5.78	0.231
Plasma albumin level (g/L)a	37.76 ± 5.71	37.84 ± 5.65	37.64 ± 5.81	0.558
Plasma urea level (mmol/L)a	19.15 (15.40–24.1)	18.90 (15.31–23.80)	19.72 (15.47–24.61)	0.093
Systolic blood pressure (mmHg)a	142 ± 21.9	144 ± 21.9	140 ± 21.7	<0.001
Diastolic blood pressure (mmHg)a	74 ± 11.3	75 ± 11.6	73 ± 10.7	0.001
Heart rate (beats/min)a	71 ± 12.6	71 ± 13.2	71 ± 11.5	0.786
Plasma creatinine level (μmol/L)a	127 ± 94.8	137 ± 89.3	127 ± 103.0	0.844
Use of ACE inhibitors, N (%)n	262 (19.8)	185 (22.8)	77 (15.0)	<0.001
Psychological/psychiatric data
Psychiatric history, N (%)a	97 (7.3)	35 (4.3)	62 (12.0)	<0.001
Depression	58 (4.4)	17 (2.1)	41 (8.0)
Dementia	15 (1.1)	7 (0.9)	8 (1.6)
Use of antidepressantsn	79 (7.7)	29 (4.8)	50 (11.5)	<0.001
Mental health scoreo	80 (60–92)	88 (80–92)	56 (46–64)	<0.001

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Continuous variables are displayed as means ± standard deviation for normally distributed variables, and as median (boundaries of interquartile range) for skewed variables. Dichotomous and categorical variables are displayed as number (percentage). ACE, angiotensin-converting enzyme.

^aComplete data available with the exception of the following variables: ethnicity 1308 (98.6%), level of education 1232 (92.9%), marital status 1290 (97.3%), smoking status 1289 (97.2%), PKD 1107 (83.5%), diabetes mellitus 1297 (97.8%), cerebrovascular disease 1283 (96.8%), cardiac disease 1187 (89.5%), peripheral vascular disease 1269 (95.7%), malignancy 1275 (96.2%), lung disease 1276 (96.2%), BMI 1230 (92.8%), nutritional status 1189 (89.7%), CCI 1290 (97.3%), eGFR 1303 (98.3%), plasma albumin level 1183 (89.2%), plasma urea level 1267 (95.6%), systolic blood pressure 1291 (97.4%), diastolic blood pressure 1291 (97.4%), heart rate 1166 (87.9%), plasma creatinine level 1303 (98.3%) and psychiatric history 1285 (96.9%).

^bEthnicity was investigator-assessed.

^cLow: primary education only; intermediate: secondary school or vocational education; high: higher professional education, or university education.

^dPatient-reported, smoking is defined as: currently smoking or smoked in the past.

^ePrimary kidney disease (PKD) was registered by the treating nephrologist, according to the diagnosis codes of the European Renal Association (ERA) [34].

^fComprising renal vascular disease, systemic diseases affecting the kidney, familial/hereditary nephropathies and miscellaneous renal disorders.

^gComprising ischaemic cerebrovascular accident/transient ischaemic attack and haemorrhagic cerebrovascular accident.

^hComprising myocardial infarct, angina pectoris, heart failure and left ventricular hypertrophy.

ⁱAny malignancy, except for basal cell carcinoma and squamous cell carcinoma of the skin.

^jComprising chronic obstructive pulmonary disease and asthma.

^kSubjective global assessment—seven-point scale, subjectively assessing the patient's nutritional status [35]. A higher SGA score indicates a better nutritional status.

^lScore summarizing patient's disease status, based on comorbidity and age. A higher CCI score indicates a higher rate of comorbidity, and therefore a worse health status [36].

^meGFR—estimated glomerular filtration rate, calculated with the MDRD formula.

ⁿData on use of medication were not available for patients originating from Sweden. Data were available for 1032 patients (77.9%).

^oMental health score indicates the score on the MHI-5 questionnaire, with a higher score indicating a better mental health (range 0–100).

Table 2.

Baseline eGFR, overall kidney function decline and incidence of adverse clinical outcomes, presented per subgroup

	Entire cohort (N = 1326)		Men (N = 883)		Women (N = 443)
Outcome	No depressive symptoms (N = 811)	Depressive symptoms (N = 515)	No depressive symptoms (N = 588)	Depressive symptoms (N = 295)	No depressive symptoms (N = 223)	Depressive symptoms (N = 220)
Baseline eGFR ± SDa (mL/min/1.73 m2)	18.95 ± 5.21	18.58 ± 5.78	18.83 ± 5.21	18.27 ± 5.59	19.26 ± 5.21	18.98 ± 6.01
Overall kidney function decline (95% CI)b (mL/min/1.73 m2/month)	–0.14 (–0.16 to –0.11)**	–0.09 (–0.12 to –0.06)**	–0.16 (–0.19 to –0.14)**	–0.11 (–0.15 to –0.07)**	–0.07 (–0.12 to –0.03)*	–0.07 (–0.12 to –0.02)*
Start of dialysisc, N (%)	237 (29.2)	142 (27.6)	189 (32.1)	95 (32.2)	48 (21.5)	47 (21.4)
All-cause mortalityd, N (%)	151 (18.6)	121 (23.5)	109 (18.5)	75 (25.4)	42 (18.8)	46 (20.9)
Combined adverse outcomee, N (%)	388 (47.8)	263 (51.1)	298 (50.7)	170 (57.6)	90 (40.4)	93 (42.3)

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^aEstimated GFR—estimated glomerular filtration rate at baseline, calculated with the MDRD formula.

^bOverall decline in kidney function, calculated by Linear Mixed Modelling.

^cNumber of patients that started dialysis during follow-up.

^dNumber of patients that died during follow-up.

^eNumber of patients that either started dialysis or died during follow-up.

*P < 0.05, **P < 0.01.

DISCUSSION

This study aimed to investigate associations between depressive symptoms and clinical outcomes in an international multicentre cohort of older patients with advanced CKD. Our results showed an association between depressive symptoms at baseline and all-cause mortality in men, but not in women. However, neither in men nor in women did we find a significant association between depressive symptoms at baseline and dialysis initiation, or with kidney function decline.

Previous studies investigating associations between depressive symptoms and clinical outcomes in patients with CKD did find an association between depressive symptoms and kidney function decline [10, 37, 38]. Recently, the association between depressive symptoms and faster kidney function decline was found in healthy adults [39]. It is possible that the sample size in our study was not large enough to detect small differences in kidney function decline related to depression using a joint model. Also, the absence of an association between depressive symptoms and faster decline in kidney function in our study might be explained by the relatively low number of eGFR measurements per patient. Otherwise, it is possible that the association between depressive symptoms and kidney function decline is more pronounced in earlier CKD stages than in advanced CKD. Presumably, in later CKD stages, other health-related factors such as physical condition are likely to be more influential on kidney function decline. The LMM analysis showed a small but statistically significant association between depressive symptoms at baseline and a slower decline in kidney function. Results of the joint model were similar, but not significant. This discrepancy in results (i.e. significance in the LMM, but not in the joint model results) may have been caused by the reduced power when using the joint model, which is also reflected by the broader 95% CIs in the joint model results compared with the LMM results.

Previous single-centre studies with smaller cohorts (between 100 and 568 participants) found an association between depressive symptoms and earlier dialysis initiation [10–12]. Follow-up of these studies was shorter than in our study, with the exception of Tsai et al. with a study duration equal to ours (i.e. 4-year follow-up) [10]. Moreover, baseline eGFR was higher in these previous studies compared with our study, and varied between 20 and 36 mL/min/1.73 m². In contrast, we did not observe a significant association between depressive symptoms and earlier dialysis initiation [10–12]. Considering the multicentre international character of our study, dialysis initiation might have differed considerably between institutions, which might have influenced our results [40]. As we did not find a significant effect of depressive symptoms on kidney function, the absence of an association between depressive symptoms and dialysis initiation is expected. Furthermore, similar to previous studies in CKD patients [10–12], we did not observe an association between depressive symptoms and mortality in our complete study population (although we did observe this association in men). However, in ESKD patients, a meta-analysis did show a significant association between depressive symptoms and mortality [3]. This inconsistency—presence of an association between depressive symptoms and mortality in ESKD patients, but not in CKD patients—might partly be explained by the higher baseline risk of mortality in patients with ESKD [41]. It should also be noted that the HRs found in our study can be considered comparable to the HR found in the meta-analysis [HR 1.51 (95% CI 1.35–1.69)], but our confidence intervals are slightly too wide to conclude that our effects are significant. Moreover, adjusting for confounding remains a challenge given the all-encompassing nature of depression and the various potential mechanisms for adverse outcomes. Our adjustment for a large number of confounders may have led to overadjustment, emphasizing the importance of also considering our unadjusted results that do align with the meta-analysis results.

Interestingly, we found an increased risk of mortality in men with depressive symptoms, but not in women. This sex-specific effect has—to the best of our knowledge—not been reported previously in patients with advanced CKD [10–12]. Nevertheless, these findings correspond with those in other populations, where studies found a stronger effect of depressive symptoms on mortality in older men compared with older women [13, 14], and with the finding of Kop et al. that the association between depressive symptoms and acute kidney injury is stronger in men than in women [38]. Although it is well known that sex affects expression of affective disorders, mechanisms underlying the interaction between sex and adverse clinical outcomes have not yet been elucidated. It was hypothesized that men do not seek treatment until their symptoms are more severe [13, 42]. Thus, supposedly, when depression is recognized in men, it is often a more severe depression.

Several mechanisms could explain the association between depression and adverse clinical outcomes, such as the higher mortality we observed in male patients. First, depression is associated with maladaptive coping styles [43], which have been shown to predict mortality [44]. As such, depressive symptoms are associated with decreased treatment compliance in ESKD patients [45, 46]. Furthermore, biological effects of depression, such as activation of the hypothalamic–pituitary–adrenal axis and increased autonomic nerve system activity might lead to increased systemic inflammation and higher risk of cardiovascular events [47–49]. Presumably, a combination of behavioral and biological factors related to depression collectively results in adverse health outcomes. Recently, a Mendelian randomization study showed an association between positive life affect and lower risk of CKD, and a negative association between depressive symptoms and eGFR [50]. This suggests a causal link between psychological characteristics and kidney function, despite non-significance in our results.

The strengths of this study include the multicentre design including patients in various countries, long follow-up duration and large sample of patients. Also, this is the first study using a joint model to account for informative drop-out in the association between depressive symptoms and adverse outcomes in CKD patients. However, our study also has limitations. First, 1326 out of 1708 patients (77.6%) answered at least three MHI-5 questions at baseline and were included, which might have led to selection bias. Second, missing data on baseline confounders might have led to biased results. However, we handled missing data with multiple imputation and maximum likelihood estimation to prevent a loss of power and biased estimates [33]. Moreover, no relevant differences were observed between patients with and without missing data, and results from analyses without imputation of missing data on confounders showed comparable results. Therefore, it is unlikely that our results were biased due to missing data. Third, ethnicity is an important factor in the relationship between depression and mortality, but our population consisted almost exclusively of Caucasian people (96.7%) [51]. A more heterogeneous population would have increased generalizability. Fourth, the observational design prevents the drawing of conclusions about causality. Although we adjusted for important baseline confounders, residual confounding is possible [34]. The similarity in the symptoms and aetiology of depression and CKD further complicates conclusions about causality [35]. However, as mentioned above, results of a Mendelian randomization suggest a causal association between positive life affect and lower CKD incidence [50]. Presumably, there is an interplay between disease progression and development of depressive symptoms. Fifth, we executed our analyses with eGFR estimated by both the Modification of Diet in Renal Disease (MDRD) formula and Chronic Kidney Disease Epidemiology Collaboration formula ensuring precise estimation of kidney function. However, accuracy of both formulas diminishes in patients with advanced age and severe CKD [36]. Finally, although our questionnaire was validated extensively, using other methods for assessing depressive symptoms (e.g. more extensive questionnaires like the Beck Depression Inventory) could potentially have resulted in greater robustness of our results [26].

This study demonstrates an association between depressive symptoms at baseline and higher mortality in men. Thus, it is possible that at least in men, antidepressant treatment might not only improve HRQOL [18, 19], but could potentially improve survival. One potential strategy to improve outcomes is cognitive behavioural therapy, which is effective in ESKD patients [52, 53]. Randomized controlled trials are needed to evaluate its effect in patients with advanced CKD. Another topic for future research is development of depressive symptoms during nephrology care in relation to adverse outcomes. The latter is important because Kimmel et al. found a stronger association between depressive symptoms and mortality when depression was treated as time-varying covariate instead of baseline predictor [6].

In conclusion, we found that depressive symptoms are associated with higher mortality in older men with advanced CKD. As the association between depressive symptoms and all-cause mortality was particularly observed in men, professionals should especially be aware of depressive symptoms in older male patients with CKD. Because this association could already be observed before ESKD, attention for and detection of depressive symptoms in men with earlier CKD stages is of great importance.

Supplementary Material

ACKNOWLEDGEMENTS

Contributor Information

Boukje C Eveleens Maarse, Department of Clinical Epidemiology, Leiden University Medical Center, Leiden, The Netherlands.

Nicholas C Chesnaye, ERA Registry, Department of Medical Informatics, Academic Medical Center, University of Amsterdam, Amsterdam Public Health Research Institute, Amsterdam, The Netherlands.

Robbert Schouten, Department of Nephrology, OLVG Hospital, Amsterdam, The Netherlands.

Wieneke M Michels, Department of Internal Medicine, Leiden University Medical Center, Leiden, The Netherlands.

Willem Jan W Bos, Department of Internal Medicine, Leiden University Medical Center, Leiden, The Netherlands. Department of Internal Medicine, Sint Antonius Hospital, Nieuwegein, The Netherlands.

Maciej Szymczak, Department of Nephrology and Transplantation Medicine, Wroclaw Medical University, Wroclaw, Poland.

Magdalena Krajewska, Department of Nephrology and Transplantation Medicine, Wroclaw Medical University, Wroclaw, Poland.

Marie Evans, Department of Clinical Sciences Intervention and Technology, Karolinska University Hospital Huddinge, Stockholm, Sweden.

Olof Heimburger, Department of Clinical Sciences Intervention and Technology, Karolinska University Hospital Huddinge, Stockholm, Sweden.

Fergus J Caskey, Renal Unit, Southmead Hospital, Bristol, UK. Population Health Sciences, University of Bristol, Bristol, UK.

Christoph Wanner, Department of Medicine, Division of Nephrology, University Hospital of Würzburg, Würzburg, Germany.

Kitty J Jager, ERA Registry, Department of Medical Informatics, Academic Medical Center, University of Amsterdam, Amsterdam Public Health Research Institute, Amsterdam, The Netherlands.

Friedo W Dekker, Department of Clinical Epidemiology, Leiden University Medical Center, Leiden, The Netherlands.

Yvette Meuleman, Department of Clinical Epidemiology, Leiden University Medical Center, Leiden, The Netherlands.

EQUAL Study Investigators :

REFERENCES