Depressive symptoms improve over 2 years of type 2 diabetes treatment via a digital continuous remote care intervention focused on carbohydrate restriction

In the United States, over 30 million people have diabetes, which is recognized among the leading causes of morbidity and mortality (Ng et al., 2014; WHO, 2016). Treatment of type 2 diabetes (T2D) usually involves recommendations for significant lifestyle changes, and when these prove insufficient, medications are prescribed to manage the disease and slow progression. However, many patients fail to maintain glycemic targets after initiation of diabetes medication; in which case dosage increases and additional medications are often required (Turner et al., 1999). Medications contribute to patient burden in terms of cost, side effects such as weight gain, and increased risk of potentially life-threatening hypoglycemia (Gerstein et al., 2008; Hayes et al., 2006; Henry et al., 1993). Further, patients often have unfavorable views of polypharmacy and treatment intensification, especially with regards to initiation of insulin therapy (Hayes et al., 2006; Polonsky et al., 2011).

The burdens of diabetes treatment are also associated with emotional distress among individuals with T2D (Fisher et al., 2008; Perrin et al., 2017). Depression and elevations in subclinical depressive symptoms are more common among individuals with T2D compared to those without T2D (Fisher et al., 2008). Treatment with insulin therapy is associated with increased risk for depressive symptoms in T2D (Bai et al., 2018), suggesting that intensive treatment contributes to emotional distress. Furthermore, depressive symptoms are associated with worse self-management (e.g., missed medical appointments, non-adherence to medications and blood glucose monitoring) (Gonzalez et al., 2008; Hoogendoorn et al., 2019) and health outcomes (e.g., hyperglycemia, diabetes-related complications, and mortality) (de Groot et al., 2001; Lustman et al., 2000; Park et al., 2013). These impacts are not restricted to people with a depression diagnosis. Even among people with relatively low levels of depressive symptoms, the number and/or severity of these symptoms are incrementally associated with poorer diabetes self-management (Black et al., 2003; Gonzalez et al., 2007). Based on this evidence, current guidelines for the psychosocial care of individuals with diabetes emphasize the importance of identifying and addressing depression and diabetes-related emotional distress as a standard of comprehensive diabetes care (Young-Hyman et al., 2016).

There has been much research dedicated to understanding relationships between depressive symptoms and diabetes (Holt et al., 2014; Moulton et al., 2015; Tabák et al., 2014). The nature and directionality of the depression–diabetes relationship is hotly debated, but evidence points to a bi-directional relationship with both behavioral and physiological mechanisms. For instance, pathophysiological alterations (e.g., hypothalamic pituitary adrenal axis dysregulation, disturbance of circadian rhythms, pro-inflammatory processes) related to insulin resistance are common to both depression and T2D (Moulton et al., 2015). Additionally, high rates of depression and emotional distress could be attributed to the stress of living with diabetes (e.g., fear of progression and complications, day-to-day burden of self-management) (Gask et al., 2011; Stuckey et al., 2014).

Sustained dietary carbohydrate restriction is recognized as an alternative to increased pharmacological treatment of T2D in the standards of medical care (American Diabetes Association, 2021). Low-carbohydrate diets have consistently elicited improvements in HbA1c, weight, inflammation and cardiovascular risk factors while reducing reliance on antiglycemic medications (Athinarayanan et al., 2019; Forsythe et al., 2007; Saslow, Daubenmier et al., 2017; Saslow, Mason et al., 2017; Saslow et al., 2018; Westman et al., 2008; Yamada et al., 2014). Despite evidence for improved diabetes outcomes up to 1 and 2 years, questions have been raised about the sustainability of the approach based on concerns relating to the burdens of adhering to the restrictive diet and the potential negative impact on patient well-being. However, the impact of carbohydrate restriction on well-being in T2D is understudied.

A burgeoning literature does not support any negative impacts of carbohydrate restriction on mood. In fact, there is a small but growing literature focused on potential mood stabilizing properties of the diet, particularly among individuals with bipolar disorder (Brietzke et al., 2018; Campbell & Campbell, 2019; El-Mallakh & Paskitti, 2001; Norwitz et al., 2020). Researchers theorize that changes in the brain (e.g., the switch to utilizing ketones for energy instead of glucose) could affect mood. In addition, a handful of studies have explored the impact of a low-carbohydrate diet on mood and other psychological outcomes among patients without mental health conditions or diabetes. The majority of studies identified either modest improvements or no change in mood or other indicators of psychological well-being (Breymeyer et al., 2016; Brinkworth et al., 2009; D’Anci et al., 2009; Halyburton et al., 2007; Harvey et al., 2019; McClernon et al., 2007; Rosen et al., 1985). A few longitudinal studies identified short-term improvement followed by regression to baseline mood (Brinkworth et al., 2009; Halyburton et al., 2007; Rosen et al., 1985).

However, there are many reasons to expect that a low-carbohydrate diet could have a positive effect on mood in people with T2D and other metabolic conditions. First, higher glucose and inflammation are linked to metabolic syndrome, diabetes, and depression (Moulton et al., 2015; Stuart & Baune, 2012); thus, improvements in glucose and inflammation observed with a low-carbohydrate diet could have a positive influence on depressive symptoms. For example, data from the Diabetes Prevention Program suggest that it is not the diagnosis of diabetes that increases risk for depression, but rather increases in HbA1c and fasting blood glucose that follow diagnosis (Marrero et al., 2015). Furthermore, improvements in HbA1c have been associated with decreased depressive symptoms in adults with T2D (de Groot et al., 2012). Second, the majority of people with T2D have obesity (Daousi et al., 2006) and the low-carbohydrate diet is associated with clinically significant long-term weight loss (Gardner et al., 2007; Sackner-Bernstein et al., 2015; Shai et al., 2008). Substantial weight loss such as that experienced following bariatric surgery is associated with improvement in depressive symptoms (Strain et al., 2014; Zwaan et al., 2011). Third, a low-carbohydrate diet tends to reduce dependence on antiglycemic medications, which is aligned with patient preferences and avoids negative secondary consequences of intensive therapy regimens, including risk of severe hypoglycemia and reduced well-being.

A few small studies have examined changes in psychological well-being among people with prediabetes or T2D in the context of a low-carbohydrate diet. Results were mixed, with some indicators of psychological well-being (e.g., diabetes distress) improving and others staying the same (e.g., depressive symptoms) (Guldbrand et al., 2014; Saslow et al., 2014; Saslow, Daubenmier et al., 2017; Saslow, Mason et al., 2017). However, the sample sizes in these small studies and time-limited carbohydrate restriction may have reduced power for these analyses of secondary outcomes.

Given the many reasons people with T2D may experience mood benefits from a low-carbohydrate diet, we conducted a secondary analysis of 2-year data from an ongoing 5-year clinical trial of a continuous remote care intervention (CCI) to explore changes in depressive symptoms. As part of the CCI, participants were coached in carbohydrate restriction with the goal of achieving nutritional ketosis (i.e., ketones, assessed via blood beta-hydroxybutyrate (BHB), ≥ 0.5 mM) to improve metabolic outcomes. The 10-week, 1-year, and 2-year primary outcomes were previously published (Athinarayanan et al., 2019; Hallberg et al., 2018; McKenzie et al., 2017). At 2 years, HbA1c decreased by 0.9% from 7.7% concurrent with significant reductions in the number and dosage of diabetes medications prescribed. Weight was also reduced by 12% at 1 year and 10% at 2 years. Inflammatory markers and most cardiovascular disease risk factors improved. In addition to metabolic outcomes, we assessed participants’ depressive symptoms at baseline, 10 weeks, 1 year, and 2 years.

Three aims guided the current analyses. First, we assessed changes in depressive symptoms over time via the average change in the total symptom severity score and the change in the percentage of participants meeting clinical cut-offs for depression. Second, we aimed to identify potential predictors of change in depressive symptoms (i.e., BHB values; change in weight, HbA1c, medication use, and inflammation) to better understand why they might be occurring. Third, we explored whether participants with evidence of baseline or historical depressive symptoms experienced the same metabolic benefits (i.e., improvements in HbA1c, weight, HOMA-IR, and fasting glucose) as participants who did not, given the links between depression and treatment adherence/engagement (Marcus et al., 1992).

During the first 2 years of an intervention emphasizing carbohydrate restriction for glycemic control, T2D participants’ mood improved. Depressive symptoms were reduced from baseline to all follow-up time points over the 2 years examined. Improvements occurred over the first 10 weeks of the intervention and then stabilized statistically, although a slight regression was observed from 10 weeks to 2 years. This is consistent with other studies of low-carbohydrate and other dietary interventions in that mood did not worsen and improvements tended to occur early in treatment (Brinkworth et al., 2009; Halyburton et al., 2007; Harvey et al., 2019; McClernon et al., 2007; Rosen et al., 1985). However, depressive symptoms appeared to regress less in the current study than other dietary studies despite the longer follow-up period. The continuous care model and sustained metabolic improvements (see Table 2 for adjusted means over time) may have contributed to the overall stability of improvements over 2 years.

Although the average change in depressive symptoms was small in this sample of adults who typically did not present with clinically significant depressive symptoms, small changes in depressive symptoms in this population are clinically important as they have been associated with better health outcomes (Feltz-Cornelis et al., 2010). Furthermore, the decreased percentage of participants meeting clinical cut-offs for depression lends evidence of clinical significance. The percentage of participants meeting the cut-off decreased from baseline to 10 weeks and 2 years but not 1 year. Given the slight regression from 10 weeks to 1 and 2 years, non-significant result at 1 year, and higher p-value at 2 years (p = 0.04), the most conservative conclusion is that reductions in probable depression diagnoses were limited to 10 weeks, although improvements in the symptom severity score were sustained for 2 years.

Because the CCI was not designed to target depressive symptoms specifically, we explored potential predictors of symptom improvement over the first 10 weeks. The percentage of daily ketone values reaching the nutritional ketosis threshold (indicating dietary adherence) was the only significant predictor of improvement in depressive symptoms from baseline to 10 weeks. To our knowledge, this is the first analysis to leverage daily ketone measurements to estimate the percentage of time participants were in nutritional ketosis and its relation to changes in mood over an extended period of time. However, this relationship is consistent with current theories regarding the potential role of ketones in mood stabilization. This is also consistent with results of the Saslow, Daubenmier et al. (2017), Saslow, Mason et al. (2017)) study in which participants with T2D who were assigned to the low-carbohydrate diet reported “liking how they felt” better than participants in other dietary conditions in a study questionnaire.

Despite literature linking weight, HbA1c, medication use, and inflammation to depressive symptoms, changes in these factors were not associated with improvement in depressive symptoms in this study. One potential explanation for the non-significant results is that qualitative perceptions of health improvement and success may be the biggest drivers of improvement in depressive symptoms. If a qualitative perception of health improvement (or psychological experiences that relate to it such as sense of control and accomplishment regarding diabetes or decreased worry about long-term complications) drives improvements in depressive symptoms, then results may be non-significant because multiple factors impact that perception. For example, a participant who experiences improvements in at least one area (e.g., HbA1c) may perceive health improvement even if changes were not seen in other areas (e.g., weight). A different combination of changes may promote this perception of success in each participant, preventing detection of effects for individual predictors. However, despite this challenge, we may have been able to detect an effect for ketones because they are the most proximal and reliable indicator of dietary adherence and hypothesized to be a cause of the improvements in all the other predictor variables (Arase et al., 1988; Ari et al., 2019; Newman & Verdin, 2014; Youm et al., 2015). Additional research is needed to better understand how all of these factors are related to mood and other aspects of health-related quality of life over time.

In preliminary analyses we discovered that baseline depression status predicted study dropout, which is consistent with studies of other lifestyle interventions (Sanderson & Bittner, 2005; Stubbs et al., 2016). To manage this bias in our data, we included baseline depressive score as a predictor in the multiple imputation model, which has been found to produce estimates very close to “true” values in a simulation (Moons et al., 2006). However, this is a limitation that must be considered in interpreting the results for aim 3 especially. For aim 3 we were interested in whether baseline depression status would predict primary metabolic outcomes (i.e., weight, HbA1c, HOMA-IR, fasting glucose) over 2 years and results depended on the way depression was defined. Given the imperfect definitions of depression, it is unsurprising that results varied. While meeting the clinical cut-off at baseline did not predict any outcomes, having a historical chart diagnosis of depression predicted worse glycemia and insulin resistance on average over the 2 years. However, the pattern of change was similar among those with and without a history of depression in that glycemia and insulin resistance improved overall over the 2 years in both groups. Baseline antidepressant use only predicted worse insulin resistance on average, which also improved similarly in both groups over the 2 years. While it is promising that results suggest the CCI is still effective for participants presenting with depression, future efforts should focus on retaining more of these participants. Research is required to better understand why participants with depression drop out at higher rates, and whether changes could be made to the CCI to better accommodate them. For example, participants with depression may require more health coach support or additional skills-building (e.g., cognitive behavioral therapy skills which have improved both depression and adherence to T2D treatment in prior research) (Safren et al., 2014) to prevent drop out. Another potential strategy is to systematically identify people with depression and connect them to high-quality depression treatment.

Limitations of this study and directions for future research should be noted. First, this was a single-arm exploratory analysis; although we hypothesize that changes in depressive symptoms resulted from the CCI, our study design does not enable us to draw any causal conclusions. Second, the CCI is multi-component making it hard to disentangle potential impacts of the dietary versus support components. Third, the sample lacked racial diversity limiting generalization of the results to all T2D patients. The sample was also relatively non-depressed and although this increased generalizability of the findings, it made it harder to detect potential effects on depression as non-depressed participants have less opportunity for improvement. Among the small subset of participants (15%) who met the clinical cut-off for depression at baseline, depressive symptoms appeared to decrease more dramatically over the 2 years (about 6 points in the depressed subset compared to about 2 points in the full sample). Future research should explore changes in depressive symptoms in a more racially diverse sample and among different subsets of the current sample, such as those with confirmed depression diagnoses. Finally, although depressive symptoms as measured by the CES-D are very important to assess, there are other diabetes-specific health-related quality of life factors that would be valuable to assess in this context. For example, diabetes distress is thought to be even more prevalent in this population than depressive symptoms and may be more strongly associated with diabetes management behaviors and outcomes (Fisher et al., 2010). Diabetes distress and other diabetes-specific quality of life factors such as fear of hypoglycemia and fear of diabetes complications may be impacted by the CCI and should receive attention in future research.