Exp Clin Endocrinol Diabetes 2023; 131(01/02): 33-50
DOI: 10.1055/a-1946-3753
German Diabetes Association: Clinical Practice Guidelines

Nutritional Recommendations for People with Type 1 Diabetes Mellitus

Diana Rubin
1   Vivantes Hospital Spandau, Berlin, Germany
2   Vivantes Humboldt Hospital, Berlin, Germany
,
Anja Bosy-Westphal
3   Institute of Human Nutrition, Faculty of Agriculture and Nutritional Sciences, Christian-Albrechts University of Kiel, Kiel, Germany
,
Stefan Kabisch
4   Department of Endocrinology, Diabetes and Nutritional Medicine, Charité Universitätsmedizin Berlin, Berlin, Germany
5   German Center for Diabetes Research (DZD), Munich, Germany
,
Peter Kronsbein
6   Faculty of Nutrition and Food Sciences, Niederrhein University of Applied Sciences, Mönchengladbach, Germany
,
Marie-Christine Simon
7   Institute of Nutrition and Food Sciences, Rhenish Friedrich Wilhelm University of Bonn, Bonn, Germany
,
Astrid Tombek
8   Diabetes Center Bad Mergentheim, Bad Mergentheim, Germany
,
Katharina S. Weber
9   Institute for Epidemiology, Christian-Albrechts University of Kiel, Kiel, Germany
,
Thomas Skurk
10   ZIEL – Institute for Food & Health, Technical University Munich, Freising, Germany
› Institutsangaben
 
Notice of update

The DDG practice recommendations are updated regularly during the second half of the calendar year. Please ensure that you read and cite the respective current version.

Updates To Content And Different Recommendations Compared To The Previous Year’s Version

Recommendation 1: Statement on the Use of Automatic Insulin Dosing (AID) Systems

Reason: How to proceed in case of system failure

Recommendation 2: Notice on dose adjustment for evening protein-rich food

Reason: Risk of hypoglycemia

Abbreviations

ADI Acceptable Daily Intake

CGM Continuous glucose monitoring

EFSA European Food Safety Authority

EN% Energy percent

GI Glycemic index

MNA Mini Nutritional Assessment

n-9RCFA Red cell phospholipid fatty acids

rtCGM Real-time CGM

iscCGM Intermittent-scanning CGM

T1Dm Type 1 diabetes mellitus

Preamble

This practice recommendation is aimed at all people with type 1 diabetes and all professional groups that care for people with type 1 diabetes.

The most recent “Evidence-based dietary recommendations for the treatment (and prevention) of diabetes mellitus” are from the year 2005 [1].

In accordance with the demand for individualization of therapy, counseling, empowerment and diabetes self-management [2] [3] and in view of the consensus report “Nutrition Therapy for Adults with Diabetes or Prediabetes” [4] [5], the Nutrition Committee of the DDG has set itself the goal of presenting evidence-based practice recommendations on nutrition for the various (sub)types of diabetes mellitus in a summarizing body of work. A separate presentation according to diabetes types and forms of treatment is considered necessary, as the therapeutic significance of nutrition differs significantly in each case and must be considered against the background of different drug therapy components. This results in the division of dietary recommendations into two sections: for people with type 1 diabetes and for people with type 2 diabetes.

Nutritional recommendations should consider the individual life and nutritional habits of each person with diabetes mellitus with the goal of maintaining the nutritional regime for as long as possible.

Many variables, such as exercise, stress, meal composition, medication, etc., have an impact on blood glucose values with a high individual variability.

Recommendations to modify the regular diet – and thus limit it from the patient’s perspective – are justified if this lifestyle change can be used to achieve a clinically-relevant health benefit or to prevent a health threat based on evidence.

It has been observed that authors of observational and experimental studies with a small number of test persons repeatedly derive general recommendations from their study results, although this is not justified, especially when it comes to recommendations for the preference of singular foods (groups).

In the practice recommendations on diet in type 1 diabetes presented here, it is clear that the evidence for general recommendations is limited. Individual testing (CGM) of the glycemic effects of food intake is important in many aspects of nutrition. The empirical values thus determined – in addition to the patient’s own food preferences – provide a suitable basis for individual food selection and the appropriate strategy for insulin application.


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Nutritional aspects in relation to glycemia and glycemic target parameters

Estimation of carbohydrate quantities

Recommendation

Patients should

  • Correctly estimate the amount of CHO ingested per meal to an accuracy of 1 carbohydrate unit (CU), equivalent to 10 g of CHO (as a basis for algorithm-guided dosing of prandial insulin)

  • Know their individual postprandial glucose trends.

  • Perform repeated testing of a standardized meal ideally via a rtCGM or iscCGM


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Comment

There are few evidence-based studies available but practical experience shows the following results. It is of crucial importance for the treatment of type 1 diabetes that patients are enabled to assess the glucose efficacy of their diet in order to adjust insulin dosage accordingly [6] [7] [8]. Structured training should provide the basis for this. The training should be repeatedly [6] [8].

There is no recommendation on the amount of carbohydrates [7] [8]. How much of each macronutrient should be eaten has to be considered on an individual basis. The evaluation of postprandial glucose trends via rtCGM and iscCGM can help to choose the right bolus variant or the correct injection-to-meal interval [9]. Especially in cases of gastroparesis, the control of different bolus variants can ensure an individually-adapted trend.

Patients with a fixed dose must estimate the correct amount of carbohydrate in their meals [7]. It is also important to estimate carbohydrate quantities correctly during pregnancy for moderate postprandial glucose trends.

Individualized nutrition and the corresponding adaptation of insulin dose algorithms can lead to a better acceptance of the disease. This is particularly important for children and adolescents. Currently, estimating the consumed carbohydrate (CHO) amounts is also recommended when using AID (Automatic Insulin Dosing) systems – with preprandial input of the CHO amount into the system. Metabolizing the carbohydrate uptake solely via the AID autocorrection cannot be recommended at present despite extensive experience. The currently-available systems are also not approved for this. In the event of an AID system failure, the correct estimation of KH quantities must be taught and mastered.

Scientific Background

There is no hard evidence for assessing carbohydrate units. In a pilot study, 256 people with T1Dm were divided into two groups: trained and untrained in nutrition. When comparing the two groups, patients with training had significantly lower HbA1c (7.8±1.3–7.4±0.9% vs. 7.5±0.8–7.5±1.1%) and less hypoglycemia [10].

In a study of 43 children aged 8.5–17.7 years with ICT, postprandial glucose trends were examined as a function of carbohydrate levels. It was shown that it is necessary to accurately estimate to within 10 g of carbohydrates to remain in the postprandial target [11]. Another study with type 1 patients exhibited similar results and the importance of good training for carbohydrate calculation [12]. The importance of this was also demonstrated in a study of 102 children and adolescents aged 8.3–18.1 years. Here the mean gram error was significantly correlated negatively with the HbA1c (r=-0.7). It was also shown that the longer the children calculated carbohydrates, the greater the mean percentage error (r=0.173). The authors therefore concluded that children and their caregivers can estimate well, but that a gram calculation is not better than a portion calculation. Repeated age-related training is necessary to reduce the error rate [13]. It has also been shown that for a good postprandial setting, accurate carbohydrate calculation within 10 g is important. In this study of 30 children (8–18 years) with CSII therapy, it was also shown that accuracy is not related to quantity.


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Glycemic index

Recommendation

  • The individual testing of the glycemic response (by glucose self-monitoring) to the preferred foods and meals is of great importance in order to develop and implement an adequate individual prandial insulin application strategy (including injection timing and application mode for CSII).

  • There is no evidence that generally giving preference to low GI carbohydrate carriers helps people with T1Dm achieve their therapeutic goals.

  • For individual meals, it is recommended to cover carbohydrate-rich foods with a low GI (below approx. 30) with significantly less prandial insulin in order to prevent hypoglycemia, especially in the case of an almost normoglycemic metabolic control.


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Comment

There are many GI tables in circulation, but only a few published in scientific papers [14] [15] [16] are suitable to be used to define the GI of carbohydrate-containing foods. In order to assess the GI, it should be taken into account that the GI values are basically average values from several studies. Variety, degree of ripeness, place of cultivation/production and, if applicable, recipe of a foodstuff all have a decisive influence on the GI. For bananas, for example, an average GI of 48 (ref. glucose=100%; volunteers: type 2 diabetes) is reported – with a range of GI 30 to GI 58 for the 9 studies considered [14]. For cooked white rice (mean GI: 59), the range even goes from GI 43 to GI 112 [14].

Studies of adults with type 1 diabetes under experimental conditions that compared the blood glucose response to (single) whole meals with low vs. high GI [17] [18] [19] have found significantly lower blood glucose responses after low GI meals and observed hypoglycemia when low GI carbohydrate carriers (lentils) are covered with the usual dose of mealtime insulin [17].

A study of blood glucose responses over a full day (4 meals per day) with insulin pump therapy [20] has shown that near-normoglycemic metabolic control is achieved regardless of GI when patients adequately adjust their insulin administration.

Medium- and long-term studies on the effects of an average low-GI diet vs. an average high-GI diet in adults with type 1 diabetes under everyday conditions are scarce; they date back mainly to the 1990s and had few participants [18] [21].

In a meta-analysis from 2010 [22], 2 studies in adults with type 1 diabetes were included; however, they exhibit methodological deficiencies and are not relevant for statements on GI [23] [24]. A recent review of the relevance of the 2018 GI in adults did not include people with type 1 diabetes [25].

Studies in children and adolescents with type 1 diabetes were mainly conducted on small numbers of subjects and under experimental conditions [26] [27] [28], so that no fundamental benefits and no favorable recommendations can be derived from them. A study from the year 2001 [29] examined 2 different dietary recommendations for 52 weeks in children with type 1 diabetes. The results of this study are often used as an argument for the benefit of a low GI diet. However, this is not justified, since the study did not intend to compare a low-GI diet with a high-GI diet, but primarily compared a diet with a fixed carbohydrate distribution (“carbohydrate framework”) vs. a diet with flexible carbohydrate intake. The evaluation of the subjects’ dietary protocols showed identical values for the mean GI of the consumed carbohydrate carriers for both groups.

Overall, there is no evidence from the available multi-week dietary studies that people with type 1 diabetes should give preference to low GI carbohydrate carriers in their diet.

With regard to the consumption of individual foods/meals (according to the “acute food/meal studies” and clinical experience), special consideration of foods containing carbohydrate with a very low GI (below approx. 30) or a very high GI (above approx. 90) seems advisable.

Foods with a very low GI (below approx. 30: e. g. pulses, nuts) should be covered with less prandial insulin to avoid hypoglycemia in the case of almost normoglycemic preprandial blood glucose values, while those with a very high GI (especially sugar-sweetened drinks) are more likely to be reserved for self-treatment of hypoglycemia.

Individual testing of the glycemic response (through glucose self-monitoring) to the preferred foods and meals is of great importance, similar to finding an optimal personal strategy for physical activity in diabetes.

In this way it is possible to determine the factors, in addition to the amount of carbohydrates ingested, which affect the postprandial blood glucose response, and these include, in addition to the GI, e. g. fluid intake, fat, protein, alcohol content of accompanying foods, preprandial glycemia, general glycemic control, body weight, physical activity, absorption of insulin from the application site.

The evaluation of postprandial glucose trends via rtCGM and iscCGM can help to select the appropriate insulin dose and bolus variant or injection-to-meal interval. People with ICT therapy can act with the options of injection-to-meal intervals or split boluses. People with CSII therapy can act via dual boluses/multiwave boluses or delayed boluses and injection-to-meal intervals. Basic criteria for the decision are initial glucose levels, carbohydrate amounts (CHO) and the GI of the diet. (Nocturnal) hypoglycemic events must be prevented especially resulting from evening meals with a very low GI.

The blood glucose response is always seen in combination with the insulin strategy. In practice, it has proven to be useful to vary the time of injection or, in the case of CSII, the insulin application mode for certain foods and starting situations according to personal experience.


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Insulin requirements for protein and fat-rich meals

Recommendation

  • There is no evidence that people with type 1 diabetes generally estimate their meals quantitatively for energy, fat and protein content in order to derive an additional insulin bolus.

  • The blood glucose response to very high-fat or high-protein meals varies from person to person and should be determined and documented by self-monitoring. On this basis, an additional insulin requirement may be developed individually.

  • Increasing the prandial insulin dose for high-protein evening meals increases the risk of night-time hypoglycemia.

  • People with type 1 diabetes should be able to assess the effect of fats and proteins on glucose levels.


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Comment

Protein-rich meals also result in a certain insulin requirement and can lead to postprandial delayed and sustained hyperglycemia [30] [31] [32]. With a carbohydrate intake of about 50 EN % and the remaining distribution to fat and protein, about 50% of the total insulin is distributed to the fast-acting mealtime insulin and 50% is covered by the basal supply. People with type 1 diabetes who have a low carb diet have a correspondingly higher basal rate and a lower proportion of mealtime insulin. However, there are situations in which low carbohydrates, high fat and protein are eaten with the main meal or in which a high proportion of fat and protein is taken in the evening via nuts, for example. In these cases, a simple bolus via mealtime insulin is usually not sufficient. One way to cover the slow glucose increase as a result of such meals would be, for example, a correction with fast-acting mealtime insulin at a later time. With CSII therapy, it would also be possible to give a delayed bolus. In order to know how much bolus to give, the FPU (fat-protein unit) was propagated as a measure.

According to Pankowska, 100 kcal of fat and protein are calculated as one CU and, depending on the amount of FPU, are delivered as a delayed bolus for a maximum of 8 h [30] [33]. In practice and in various studies, however, it has been observed that this formula cannot be used equally well for all people with type 1 diabetes. In a paper by Hermann, a calculation with 200 kcal corresponding to one CU was compared [34]. In this work it was confirmed that hardly any formula can be applied equally well to everyone. In a pilot study with nuts, the same result was also obtained [35]. Glucose increases can be observed after eating foods rich in fat and protein, but the insulin dose must be determined and trained individually. Increasing the prandial insulin dose for high-protein evening meals increases the risk of night-time hypoglycemia.


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Fiber and glycemic control

Recommendation

  • There is not yet sufficient evidence that people with type 1 diabetes should eat a high-fiber diet to achieve their glycemic therapy goal.

  • Possible effects of a fiber-rich diet on other health-promoting aspects (e. g. cardiovascular diseases, intestinal health, weight management) should be considered separately and individually.

  • The increased consumption of high-fiber foods seems to have a positive effect on the trend of postprandial glycemia, but the recommendations for fiber intake are based on those for the general population (30 g per day).


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Comment

A fiber-rich diet is generally considered to be beneficial to health, especially in the case of diabetes mellitus. The German Nutrition Society (Deutsche Gesellschaft für Ernährung) recommends a daily intake of at least 30 g of dietary fiber for the general population, which is not achieved by the average German population [36]. So far, there are no evidence-based recommendations for a certain amount of dietary fiber in diabetes. Although many studies have been designed for type 2 diabetes, there is often no explicit differentiation between diabetes types, although there are certain aspects that require separate consideration [37].

In later life, for example, the study situation for high-fiber diets (DASH diet, vegetarian, vegan) is inconsistent regarding, e. g., renal endpoints, but there is a small indication to the benefits of vegetarian diets in a systematic review [38]. Lower blood pressure [39] and a lower inflammatory load are positive outcomes of higher dietary fiber intake in T1Dm [40].

In terms of weight management, dietary fiber plays a strong role, at least in type 2 diabetes, when consumed as part of a diet that has a low glycemic index [41]. Fiber contributes to a reduction in energy density and a lowering of the glycemic index and positively modulates the blood glucose profile. Observational studies in subjects with T1Dm have also shown an association with lower HbA1c levels, but the association was only mildly significant, possibly explained by the suboptimal amount of dietary fiber ingested (mean value 16 g fiber per day) [42].

To investigate the influence of the microbiota, prebiotics were used to improve bacterial diversity. Inulin led to an increase in bifidobacteria in young type 1 diabetes patients (<17 years) and simultaneously to a higher C-peptide value than in the control group [43].


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Supply of sucrose and fructose

Recommendation

  • Beyond general recommendations, there is no evidence of specific recommendations for reducing added sucrose in individuals with T1Dm.

  • Foods containing naturally-occurring sugars (glucose and fructose) should not be restricted in the diet of people with type 1 diabetes.

  • The evidence base for the recommendation of a reduction of added fructose is uncertain.


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Comment

The evidence for adult individuals with T1Dm regarding recommendations for sucrose and fructose intake is limited. With regard to the intake of added sugar, current evidence-based guidelines generally recommend that people with diabetes mellitus minimize their intake of added sugar and replace it with foods with a higher nutrient density [4] [6] [7]. The majority of the European professional societies express the recommendation to reduce the intake of sugar (primarily free or added sugars) for the general population as well. Recommendations that state a suggested upper limit usually set this at 10 EN % for adults and 5 EN % for children>2 years [44]. However, according to the dietary recommendations of the American Dietetic Association for people with T1Dm and T2Dm, sucrose intake of 10–35 EN % has no negative effects on glycemic or lipid response when sucrose isocalorically replaces starch [45]. A similar conclusion, namely that a sugar intake at a level common in human nutrition does not lead to undesirable metabolic health effects, is drawn by Rippe et al. in their review of randomized controlled trials [46].

In a randomized, controlled trial over the span of 3 months in which 33 persons with T1Dm received either a sucrose-free or a sucrose-enriched diet (mean sucrose or fructose intake after the intervention: 2 vs. 27 EN % or 6 vs. 9 EN %), it was also confirmed that although higher concentrations of inflammatory markers (C-reactive protein) were detectable in subjects with higher sucrose intake, the two groups did not differ in insulin requirements, glycemic control, anthropometric parameters, body composition, or triglyceride concentrations [47].

Scientific Background

The intake of fructose with regard to diabetes mellitus is intensively discussed due to its metabolization different to glucose. Since fructose is first metabolized in the liver, it does not lead to an increase in blood glucose levels, unlike glucose, and thus does not trigger the release of insulin. Furthermore, fructose is converted to free fatty acids during de novo lipogenesis, but only to a small proportion of about 1–5% [48]. Systematic reviews and meta-analyses, which included individuals with T1Dm, as well as a randomized controlled trial with T1Dm patients, show lower postprandial peaks for blood glucose, lower total cholesterol concentrations, no differences in other serum lipid parameters, but possibly increased uric acid concentrations and oxidative stress in an isocaloric comparison of fructose with other carbohydrates [49] [50] [51] [52]. Due to the hepatic metabolization of fructose, its influence on hepatic insulin sensitivity is also widely discussed. The evidence for persons with and without T2Dm shows that only a very large increase in fructose intake to approximately 80 g/d leads to a moderate reduction in hepatic insulin sensitivity, without an accompanying clinically-significant increase in fasting blood glucose concentrations [53].

In summary, the rationale for a reduction in sucrose and fructose intake for adults with T1Dm due to a lack of evidence for this group of people is primarily derived from the evidence for the general population or, more generally, people with diabetes and is based on the recommendations of a balanced diet: although an isocaloric replacement of foods containing sucrose or fructose with other carbohydrates may have similar effects on blood glucose levels or other metabolic parameters, consumption should be minimized in favor of foods with a higher nutrient density [54], and the selected foods containing carbohydrates in the diet should ideally be rich in fiber, vitamins, minerals and low in added sugars, fats and sodium [55].

For children and adolescents with T1Dm, the following study results can also be taken into account to justify a reduction in sucrose and fructose intake: data from a review and observational study show that a higher sugar intake is associated with the development of T1Dm in childhood [56] and that the late phase of disease development in particular could be accelerated [57]. In adolescents with manifest T1Dm, fructose intake was directly associated with triglyceride concentrations [58]. However, the intake of naturally-occurring sugars (within the normal range of the diet) was associated with improved parameters of glycemic control, and Nansel et al. conclude that foods containing this source of sugar do not have negative effects on blood glucose control in adolescents with T1Dm [59].


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Use of sweeteners

Recommendation

  • Sweeteners can be useful as an occasional addition to foods and beverages as part of a diabetes-compliant diet and insulin therapy and are harmless to health as long as they are consumed below the respective maximum amounts.


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Comment

The topic of “sweeteners” is a recurring topic of discussion in nutrition. Sweeteners are synthetically produced or natural compounds with a high sweetening intensity, which are metabolized independently of insulin and are not cariogenic. Even though the calorie content of some sweeteners is 4 kcal/g, just like conventional sugar (sucrose), they are only used in very small amounts in the milligram range due to their high sweetening power, so that calorie intake is negligible. As additives, sweeteners are subject to a health assessment by the European Food Safety Authority (EFSA) prior to approval, which determines acceptable daily intakes (ADI). The ADI value indicates the amount of an additive that can be ingested daily per kilogram of body weight over a lifetime without causing health risks. Even after approval, the EFSA continues to further investigate the sweeteners if necessary. Although sweeteners are therefore considered to be harmless to health according to the current state of knowledge, possible long-term health consequences in particular have been discussed repeatedly for many years.

The reservation of an increased cancer risk from sweeteners is mainly based on older studies, which are based on results from animal experiments. However, these studies used very high amounts of the sweetener in question, far in excess of the acceptable daily intake for humans, so the results are not transferable to humans. According to recent animal studies and available human data, there is no evidence of an increased cancer risk from sweeteners if the ADI values are adhered to [60] [61].

An increase in weight caused by sweeteners has not yet been scientifically proven. The clinical studies on this topic sometimes diverge considerably. Epidemiological studies predominantly conclude that sweetener consumption is associated with an increased risk of excess weight or obesity. By contrast, studies with higher evidence levels tend to indicate a weight-neutral effect or that sweeteners are a tool that can be used with limitations for reducing energy intake and weight control [62] [63].

Some observational studies show a positive association between sweetener consumption and the risk of type 2 diabetes and other cardiometabolic diseases, but the bias of excess weight and reverse causality is often a problem [61] [63] [64].

Regarding the effect of sweeteners on appetite, intervention studies show that beverages containing sweeteners have an effect similar to water on appetite and energy intake [63] [65] [66]. A recent review of various studies investigating the effect of sweeteners on the appetite and consumption of sweetened products also showed no increase in either appetite or consumption [67].

With regard to the effects on human intestinal microbiota, the data is limited and does not provide sufficient evidence that sweeteners at the levels relevant for human consumption have a negative impact on the microbiota [63] [68].

The potential benefit of sweeteners in patients with type 1 diabetes is mainly due to their use as a substitute for sugar without triggering a glycemic response. Despite controversial discussions, current research provides collective evidence that the consumption of sweeteners has no adverse effects on blood glucose and insulin regulation (HbA1c, fasting and postprandial glucose and insulin levels) in people with and without diabetes [63] [69].

In general, research on sweeteners is hampered by the chemical and metabolic heterogeneity of sweeteners, their, at times, combined use in different product groups and the changing trends in consumer behavior [61] [70].


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Effective blood glucose food for hypoglycemia

Recommendation

  • Persons with T1Dm and mild hypoglycemia (can be treated by the patient) should consume 15–20 g of rapidly absorbable carbohydrates. This measure should be repeated after 15 min if blood glucose concentrations remain low.

  • Persons with T1Dm and severe hypoglycemia experiencing confusion or clouding of consciousness should consume 30 g of rapidly absorbable carbohydrates. In individual cases, it may be necessary to supplement with 15–20 g of slowly resorbable carbohydrates.


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Comment

Rapid carbohydrates such as oral glucose in solid and liquid form are particularly suitable for treating hypoglycemia. Furthermore, sucrose-containing beverages such as lemonades and juices can be used.

In some cases, slowly resorbable carbohydrates can contribute to the stabilization of blood glucose depending on the situation [6] [7] [8].

In order to preventatively avoid hypoglycemia, in special situations, rapidly resorbable carbohydrates should be ingested beforehand to increase the target value and slowly resorbable carbohydrates should be supplemented to stabilize the trend. The amount should be chosen individually and depend on the situation. Classic situations that can result in hypoglycemia are physical activity and alcohol consumption [6].

People who suffer from severe hypoglycemia, who can no longer undergo self-therapy or who are unconscious should not be given oral carbohydrates. In these cases, treatment with glucagon by family members or relatives is possible or professional IV glucose administration. Friends and family members should be trained in the use of glucagon kits [71].


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General nutrition aspects

Protein consumption

Recommendation

  • There are contradictory statements regarding the benefit/damage for limiting or increasing protein intake as part of a specific diabetes diet. At most, a limitation of the daily protein intake may be useful under a few specific circumstances in existing kidney diseases.


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Comment

Increased protein intake has been scientifically studied in people with type 1 diabetes mellitus, particularly with regard to the acute glycemic response [72]. In this context, reference is made to the recommendation on “Insulin requirements for protein and fat-rich meals”.

No evidence has been shown that increased protein intake leads to positive or negative effects in people with type 1 diabetes.

A limitation of protein intake has been studied, especially with regard to slowing the progression of diabetic nephropathy.

In general, RCT with intervention times>6 months show that protein targets<0.8 g/kg body weight/d are rarely met even under study conditions.

In a larger randomized controlled trial, a low-protein diet in people with type 1 or 2 diabetes and nephropathy achieved significant improvements in GFR when compliance was good [73].

In another methodologically well-conducted study, limited protein intake also appeared to slow the progression of diabetic nephropathy, but the effects were not significant. Compliance was also poor in this study and difficult for patients to maintain. Another study showed no difference in the rate of progression of diabetic nephropathy with low normal protein intake (0.8 g/kg body weight, 16 EN %) vs. high normal protein intake (19 EN %) [74].

In summary, the evidence for a recommendation for protein reduction – even in diabetic nephropathy – is insufficient. In individual situations and taking into account a high biological value of the proteins, a mild protein restriction may be justified with the aim of inhibiting the progression of diabetic nephropathy. However, this should always be accompanied by professional nutritional advice, since there is a risk of malnutrition especially in advanced stages of renal insufficiency.


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General Nutrition Aspects

Fat intake

Recommendation

  • No specific recommendation can be made for the amount of fat intake in people with T1Dm.

  • Effects of the fatty acid composition (fat quality) on other health-promoting aspects may need to be considered separately. However, the fat quality should be in accordance with the recommendations for the general population.


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Comment

For the acute blood glucose response after fat intake, please refer to the chapter “Insulin requirements for protein and fat-rich meals”.

The popularity of low-carbohydrate and thus mostly high-fat diets is high. However, high-fat and low-carbohydrate diets have not been well studied in the treatment of type 1 diabetes. Studies that looked at glycemic outcomes from low-carbohydrate diets were mostly cross-sectional studies without validated nutritional data and without control groups. Participants were highly motivated, self-selected individuals who used intensive insulin management practices, including frequent blood glucose monitoring and additional insulin correction with narrow glycemic targets. Therefore, these results are not necessarily transferable to patients with type 1 diabetes in general. Carbohydrate-containing foods such as cereals, fruits and milk are important sources of nutrients. Therefore, low-carbohydrate diets require attention to vitamin and energy intake to avoid micronutrient deficiencies and growth problems in children. Following restrictive diets is a challenge and can affect social normality. People with type 1 diabetes also theoretically have adverse health risks such as diabetic ketoacidosis, hypoglycemia, dyslipidemia and glycogen deficiency [75].

In general, observational studies often associate high fat and low carbohydrate intake with higher BMI [76], but this does not allow the conclusion to be drawn that low fat and high carbohydrate intake is generally recommended. Observational studies often do not address the quality of the fats and carbohydrates ingested, so that it is not taken into account that too many low-value fats and too few complex carbohydrates are usually ingested (see also DDG statement on ADA Recommendations 2019 [5]).

Rather, randomized, controlled intervention studies evaluating the quality of macronutrients should be considered to answer the question of modifying fat intake for people with type 1 diabetes.


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Eating Patterns

Recommendation

  • For people with T1Dm there are a variety of dietary patterns that are suitable. The available evidence is insufficient to recommend a dietary pattern for successful diabetes management.


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Comment

According to the recommendations of the American, Canadian, and British diabetes associations, there are a variety of dietary patterns that are suitable for people with diabetes. For example, a diet based on the Mediterranean diet or the Dietary Approaches to Stop Hypertension (DASH) diet could help improve glucose metabolism and weight control and reduce cardiovascular risk factors. However, low-carbohydrate, vegan/vegetarian, plant-based diets, or a diet rich in legumes could also be suitable for people with diabetes. Individual preferences, goals and needs should influence the choice of dietary pattern [6] [7] [8]. Even specifically for people with T1Dm, the American Diabetes Association says that there is insufficient evidence to make one dietary pattern more recommendable than another [6].

Further evidence from intervention and observational studies for individuals with T1Dm is available on the Mediterranean diet, the DASH diet, the Healthy Eating Index (HEI) or Alternative Healthy Eating Index (AHEI) and the Whole Plant Food Density (WPFD) score. In a cohort study of 118 adults with T1Dm, a Mediterranean diet was associated with a favorable cardiometabolic profile [77], whereas a 6-month intervention study of 28 adults with T1Dm and metabolic syndrome showed no superiority of a Mediterranean vs. low-fat diet in terms of anthropometric and metabolic parameters [78]. In 96 children and adolescents with T1Dm, structured nutritional training for a Mediterranean diet improved the quality of nutrient intake, followed by an improvement in serum lipid levels [79]. In a 5-year longitudinal observational study of 500 children and adolescents with T1Dm, greater adherence to the Mediterranean diet was also associated with better glycemic control and better serum lipid levels [80].

In the SEARCH for Diabetes in Youth Study, it was observed in 2 cross-sectional analyses of 2440 and 1810 adolescents with T1Dm that greater adherence to the DASH diet is inversely associated with hypertension, HbA1c levels and the LDL-HDL ratio [81] [82]. However, in a preliminary controlled intervention study in 16 adolescents with T1Dm, participants on the DASH diet were shown to have increased glycemic variability compared to their usual diet. Adapting the DASH diet to people with diabetes (e. g., 30 EN % from fat instead of 20 EN %) resulted in a glycemic variability comparable to the usual diet, but with lower average blood glucose concentrations and less time in the hyperglycemic range [83].

The role of HEI, an index measuring compliance with U.S. dietary recommendations, was investigated in 4 observational studies in children and adolescents with T1Dm. The studies showed conflicting results regarding the association between the HEI and glycemic control, and no association between the HEI and cardiovascular biomarkers [84] [85] [86]. In an observational study of 12 subjects with T1Dm and 75 subjects with T2Dm (no stratified analysis), greater adherence to the alternate healthy eating index (AHEI) was prospectively associated with improved vascular health [87].

Two cross-sectional studies in adolescents with T1Dm showed that neither the Mediterranean diet, the DASH diet, nor the HEI was associated with selected biomarkers of inflammation, and that only the HEI was inversely related to microalbuminuria, which was no longer significant after adjustment for HbA1c and systolic blood pressure [88] [89].

Greater adherence to whole grains, fruits, vegetables, legumes, nuts, and seeds was associated with better glycemic control in a longitudinal observational study in adolescents with T1Dm [72].

In addition to the evidence for the above described hypothesis-based dietary patterns, 4 cross-sectional and one longitudinal observational study investigated associations between exploratory dietary patterns and metabolic parameters such as glycemic control and blood pressure, inflammatory biomarkers, serum lipid levels, and vascular health parameters in subjects with T1Dm [90] [91] [92] [93] [94]. These studies also confirm the conclusion of medical societies that there are a variety of dietary patterns that may be beneficial for people with diabetes, in this case T1Dm [6] [7] [8].


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Meal frequency and meal timing

Recommendation

  • If people with T1Dm are overweight, they should avoid irregular eating times, eating late and a time window for daily food intake>12 h. Instead, they should consume the calories predominantly in the first half of the day, as this can have a beneficial effect on body weight regulation and cardiometabolic risk.

  • A recommendation for fasting during the day (<3 meals per day) or modified intermittent fasting on one or more days a week cannot be given.


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Comment

Irregular food intake, such as skipping meals and snacking behavior, where small portions are often eaten between meals and almost around the clock, is a characteristic of the modern lifestyle [138]. To investigate the influence of frequency and timing of food intake on energy balance and cardiometabolic risk, studies in healthy individuals and subjects with high metabolic and cardiovascular risk are considered below.

A high meal frequency could increase the risk of obesity [139] [140], as many small meals lead to less satiety than 3 larger meals with the same energy intake [141] [142]. In addition, frequent smalls meals compared to fewer meals with the same energy intake resulted in higher liver fat content [142] [143].

On the other hand, lower meal frequency, lower caloric intake at breakfast or complete skipping of breakfast was associated with higher weight gain and increased risk of diabetes, heart attack and stroke in prospective long-term studies [144]. Intervention studies of varying durations provide further evidence that skipping breakfast and/or lunch does not have consistently positive effects on body weight regulation or glucose metabolism [138] [145], [146] [148] [148]. In contrast, skipping the evening meal and eating three meals by early afternoon resulted in improved insulin sensitivity, ß-cell response, blood pressure, and appetite compared to an isocaloric breakfast, lunch, and dinner protocol [149] [150].

The influence of the time of mealtime intake on body weight and cardiovascular and metabolic risk is partly explained by circadian differences in metabolism (e. g. with regard to insulin sensitivity). On the other hand, the circadian clock, with the help of clock genes and clock-controlled genes, uses food intake as a timer, so the timing of meals can have an influence on the energy balance and metabolic risk [151]. If food is consumed mainly in the evening or at night, contrary to the natural circadian rhythms, e. g. by skipping breakfast, this leads to lower postprandial thermogenesis and higher postprandial glycemia and insulin response [152]. Consuming low GI foods in the morning leads to a greater improvement in glycemia than consuming them in the evening [153].

In addition, a long daily time window in which energy is ingested, independent of the time of food intake, promotes weight gain [138]. A reduction of the daily time window during which food was eaten from more than 14 h to 10–12 h led to weight loss with an otherwise unchanged diet [154].

Intermittent fasting is a popular concept for weight loss based on major cycles of dietary restriction, which do not involve skipping a single meal, but instead provide a greatly reduced calorie intake (0 to<25% of energy requirements) every 2nd day or 2–3 times a week. Intermittent fasting results in significant weight loss depending on the frequency of the fasting days, but this is no different from the success of a reduction diet with continuous energy restriction [155] [157] [158] [158]. The effects of this negative energy balance lead to a differently pronounced reduction of cardiometabolic risk factors depending on the level of the initial values.

There are worries that intermittent fasting increases the variability of glycemia by increasing the risk of both hypoglycemia and postprandial hyperglycemia [159], [160]. The lack of superiority of intermittent fasting over continuous, moderate calorie restriction and the lack of studies on the risks and long-term results in subjects with T1Dm make a recommendation for intermittent fasting impossible.


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Recommendations for body weight

Recommendation

  • People with T1Dm and normal weight should maintain a normal body weight.

  • The study situation is not sufficient to generalize the recommendation for weight reduction to people with type 1 diabetes and excess weight. However, the recommendation for weight reduction may be useful in the presence of concomitant diseases or insulin resistance (e. g. secondary dyslipoproteinemia, high blood pressure, steatohepatitis, etc.).

  • The quality of food and possible hypoglycemia should be considered, especially in low-carb diets. This may also result in eating disorders.


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Comment

A higher BMI is associated with macrovascular disease and retinopathy in type 1 diabetes [6] [7]. There are no evidence-based studies showing an association between weight and glycemic control in type 1 diabetes. However, it can be assumed that weight loss in type 1 diabetes with simultaneous insulin resistance or parallel metabolic syndrome has similar effects to type 2 diabetes [78] [83] [154].

Therefore, weight reduction in obese T1Dm patients is likely to be beneficial in a diet with a low caloric density but high nutritional quality, especially if the aim is to predominantly reduce abdominal fat.

Very-low-carb diets, formula diets or interval fasting may increase the risk of hypoglycemia and should be used only with close adjustment of the insulin regimen and discussed with the diabetes team.

There is no scientific evidence for the superiority of a nutritional concept (e. g. low-carb or low-fat) in terms of weight loss for T1Dm. Regarding meal frequency, please refer to the text section “Meal Frequency and Meal Timing”.

Particularly with the somewhat younger T1Dm patients, the patient desire for weight reduction must be critically weighed against the risk of developing or succumbing to an eating disorder. Female patients are particularly vulnerable compared to male T1Dm patients, [161]. A survey of 34 normal and overweight T1Dm patients showed that weight management and metabolic control measures often contradict each other. This can result in conflict potential and incompliance [162].

Bariatric surgery as a method for weight reduction in patients with T1Dm is to be evaluated critically and must be coordinated with the obesity team and the diabetes team on a case-by-case basis.

Weight reduction in obese T1Dm patients as a side effect of a generally metabolically-beneficial diet is likely justifiable, especially if predominantly visceral fat deposits are to be reduced. However, there is insufficient data on this. Very-low-carb diets or interval fasting can increase the risk of hypoglycemia and should therefore only be used with close adaptation of the insulin regimen.

Scientific Background

One study compared a weight loss diet high carb/high fat versus high carb/low fat, with no difference in HbA1c [183].

Observational studies or studies with small numbers of test persons on the consumption of unsaturated fatty acids, n-9 fatty acids or olive oil have not yet provided a reliable basis for recommendations.

In a Spanish observational study, uptake of PUFAs/SFAs>0.4 and MUFAs/SFAs>1.5 was associated with near-optimal metabolic control goals and a reduction in the risk of diabetic complications [184].

This is supported by another RCT that showed that increased uptake of MUFAs leads to improved glycaemia. A 10% increase in n-9 RCFAs was associated with a 0.64% improvement in HbA1c [185]. Correspondingly, an RCT showed that acute glycemia was more favorable after olive oil than after butter [186].


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Dietary recommendations for weight maintenance

Recommendation

  • There is no specific recommendation for maintaining weight with T1Dm.


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Comment

Studies on the optimal diet for weight maintenance at T1Dm are not available. The recommendations should be based on the DGE guidelines for healthy individuals, but without defining a specific proportion of macronutrients.

Nutritional intervention studies without weight loss differed in the metabolic outcome. With Mediterranean diet (n=96) the lipid profile improved, with low-fat diet (n=10) insulin sensitivity in T1Dm patients was also reduced [163].

In individual cases and when used in moderation, carbohydrate reduction can be safe and with few side effects but without particular benefit (Case Report) [171]. However, the risk of hypoglycemia is increased when short-acting insulins are used with “low carb” [172]. In contrast, other studies also show a reduction in the risk of hypoglycemia with even a severe reduction in carbohydrates (<50 g; n=10, 1 week). Ketonuria as an indicator of insulin deficiency is limited [173]. The effectiveness of emergency glucagon is also reduced due to the lower liver glycogen content [169].

Diets rich in carbohydrates are without advantage or disadvantage when the insulin dose is adjusted (n=9, 4 weeks) [174], lower insulin requirements are necessary in the case of a high-fiber variant (n=10, 4 weeks) [175], but on the other hand can be associated with a worsening of the metabolic situation – even during intense physical activity (n=7, 3 weeks) [176].

Qualitative differences of carbohydrates influence the glucose increase for T1Dm. Complex carbohydrates should be used to optimize therapy (n=12, one-time acute test of rice vs. pasta varieties) [177]. However, the benefit of a glycemic diet is limited (n=11; 12 weeks, no control group) [178]. As in healthy individuals and T2Dm, soluble dietary fiber (e. g. guar) does not show the long-term benefit in terms of glycemic control (n=8; 4 months) but is still recommended as a component of natural foods for other metabolic reasons [179].

Short-term interventions with the aim of avoiding weight gain, e. g. via VLCD days or short-term intermittent fasting (8:16), require individual continuous glycemic control in order to ensure or optimize the suitability of the applied insulin dosing strategy for such days.


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Nutritional aspects in geriatric patients

Recommendation

  • There are no special dietary recommendations for elderly or geriatric persons with T1Dm.

  • The goals in nutrition therapy often have a different focus and focus on maintaining independence more than the actual glycemia and, in geriatric patients, on avoiding malnutrition and hypoglycemia.

  • The recommendations of a protein intake that meets the needs (at least 1 g/kg body weight/d) and the maintenance of a BMI that is up to slightly overweight are basic measures that correspond to the recommendations for the general population and also apply to this group of people.


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Comment

Basically, the nutritional recommendations for older people with T1Dm do not differ from those for older metabolically healthy or younger people with T1Dm. At the same time, the general nutritional recommendations for geriatric patients apply to geriatric patients with T1Dm. Especially in functionally-dependent patients, the consequences of malnutrition in old age are severe and should be focused on in patients with T1Dm. For example, the loss of muscle mass associated with weight loss reinforces the age-related sarcopenia and frailty, thereby promoting disabilities and loss of independence.

The S2k guideline “Diagnosis, therapy and follow-up of diabetes in old age” also contains very detailed recommendations for the general nutritional therapy of elderly people with diabetes. It makes it clear that therapeutic goals – also with regard to nutrition – can, but need not, often change in older and especially geriatric patients. Functionality and the preservation of independence are in the foreground.

Although an improvement in insulin sensitivity could also be achieved in older people through an intended weight reduction [180], strict dietary restrictions should be avoided in older people who are overweight or obese due to the risk of malnutrition. Dietary restrictions that may limit food intake are potentially harmful and should be avoided. If weight loss is being considered, dietary measures should be combined with physical activity whenever possible, and the focus should be on protein intake to meet the needs. A significant increase in mortality was only found in people over 65 years of age when their body mass index (BMI) exceeded 30 [180]. Restrictions in the consumption of familiar and comfort food lead to a reduction in the subjectively-perceived quality of life. This aspect is particularly important for people in old age.

The risk of potential malnutrition is present if the reduced food intake continues (approximately<50% of the requirement for more than 3 days) or if several risk factors are present at the same time, which either reduce the amount of food or significantly increase the energy and nutrient requirements. The risk of malnutrition can be assessed e. g. by MNA or the corresponding short form (SF-MNA), both screening methods are well evaluated [181] [182]. In underweight patients, the causes should be clarified and, if possible, eliminated.

Nutritional therapy should also focus on the prevention of hypoglycemia, with an initial focus on the adjustment of medication.

For further information, especially for persons with diabetes in nursing homes and if artificial nutrition is necessary, please refer to the S2k guideline “Diagnosis, therapy and follow-up of diabetes in old age” and the S3 guideline “Clinical nutrition in geriatrics” (DDG 2018, DGEM 2013).

Due to the complexity of the often multimorbid geriatric patients, planning and implementation of disease-specific diets should, if necessary, be carried out by a multi-professional team including a nutritional expert.


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Nutritional aspects of special foods and nutritional supplements

Sugar-sweetened beverages

Recommendation

  • With the exception of treating hypoglycemia, people with T1Dm should minimize their intake of sugar-sweetened beverages.


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Comment

Similar to the evidence for sucrose and fructose intake in people with T1Dm, the data on the intake of sugar-sweetened beverages specifically for this group of patients is also limited, so that recommendations made for the general population and for people with diabetes in general must also be used. According to the current evidence-based guideline of the American Diabetes Association, the intake of sugar-sweetened beverages is strongly discouraged for people with diabetes, and water is recommended as often as possible to control blood glucose levels and body weight, and reduce the risk of cardiovascular disease and fatty liver (evidence level B) [4] [6]. The British Diabetes Society rates the evidence on reducing the intake of sugar-sweetened drinks as low but agrees that reducing the consumption of sugar-sweetened drinks reduces cardiovascular risk (Grade 2) [7].

For the general population, a low intake of sugar-sweetened beverages is recommended, among other things, because of their high energy content and the resulting risk of obesity. Limiting their intake is recommended because it contributes to an increased micronutrient density and reduced sugar intake [95]. Minimizing their intake and replacing them with water or unsweetened milk or dairy products is also recommended specifically for children and adolescents, regardless of their diabetes status [95]. According to the American Heart Association, the maximum amount for this age group should be around 237 ml per week [95].

For persons with T1Dm, data for children and adolescents is available from 2 observational studies. The Diabetes Autoimmunity Study in the Young observed 1839 children and adolescents with an increased genetic risk for T1Dm over a mean duration of 10.2 years. In study participants with a high-risk HLA genotype, but not in those with a low or medium risk for T1Dm, the progression from islet autoimmunity to T1Dm was associated with an increased intake of sugar-sweetened beverages [96]. Based on cross-sectional analysis of the SEARCH for Diabetes in Youth Study, it was shown that in children and adolescents with manifest T1Dm, a higher (at least one serving per day) intake of sugar-sweetened beverages was associated with higher levels of total cholesterol, LDL cholesterol and plasma triglycerides, compared to no intake of sugar-sweetened beverages. However, these associations were partially explained by an adjustment for BMI, saturated fat and fiber intake. No association was found between the intake of sugar-sweetened beverages and HbA1c, blood pressure, and HDL cholesterol [97] [98]. A high intake of sugar-sweetened beverages may therefore have a negative effect on the cardiovascular risk profile in children and adolescents with T1Dm and they should be encouraged to minimize their intake [97].


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Alcohol

Recommendation

  • People with T1Dm should limit the amount of alcohol consumed to the amounts recommended for the general population. Moderate, low-risk alcohol consumption is compatible with good metabolic control and diabetes prognosis.

  • People with diabetes with risky alcohol consumption or an alcohol dependency should be informed about the dangers of alcohol, especially with regard to poorer metabolic control and the risk of secondary diseases.

  • It should generally be noted that consumption of larger amounts of alcohol increases the risk of severe hypoglycemia, especially at night. This risk is reduced by eating during the period of alcohol consumption and raising the target blood glucose level into the night.


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Comment

People with diabetes should be advised of the effects of alcohol consumption on blood glucose levels and, if alcohol is consumed, should be encouraged to stick to low-risk consumption amounts. The German Head Office for Addiction Issues e. V. (Deutsche Hauptstelle für Suchtfragen e. V. – DHS) specifies 12 g alcohol per day for women and 24 g alcohol per day for men as limits for low-risk consumption. The World Health Organization (WHO) defines a consumption of 10 g alcohol per day for women and 20 g alcohol per day for men as low-risk. These amounts also apply to people with type 1 diabetes.

The consumption of alcohol can affect blood glucose counterregulation and thus increase the risk of hypoglycemia. About one in five cases of severe hypoglycemia leading to hospitalization is caused by alcohol consumption. However, the main effect of alcohol is likely to be reduced awareness, which leads to a limited perception of hypoglycemia and prevents those affected from reacting appropriately. A systematic review on this issue is available from 2018 [187]. A total of 13 studies (RCT and observational studies) were evaluated.

Eight studies reported that ethanol – regardless of whether administered intravenously or orally – was associated with an increased risk of hypoglycemia, which was linked with a decrease in plasma glucose, an impaired counterregulatory response, hypoglycemia perception disorder, and impaired cognitive function.

Five studies could not prove an increased risk of hypoglycemia. None of the studies investigated prevention strategies for ethanol-induced hypoglycemia. Recommendations from 13 diabetes associations were included. All associations recommend only consuming ethanol together with food. The majority of the included studies showed that ethanol consumption increased the risk of hypoglycemia in patients with T1D. However, the evidence for the prevention of ethanol-induced hypoglycemia is scarce and further investigation is needed to provide evidence-based recommendations.

Excessive consumption of alcohol interferes with diabetes therapy. Patients with excessive or risky alcohol consumption are less likely to implement therapy recommendations on exercise, diet, medication, blood glucose self-monitoring or regular HbA1c monitoring. There is a linear relationship: the higher the drinking volume, the less frequently therapy recommendations are implemented.

According to the S2k guideline “Psychosocial factors and diabetes”, people with diabetes should be surveyed regularly – at least once a year – for their alcohol consumption, and help should be offered to patients with risky alcohol consumption.


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Nutritional supplements

Recommendation

  • People with T1Dm should cover their nutritional needs with a balanced diet. Routine supplementation with micronutrients is not recommended.


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Comment

The American and Canadian diabetes associations summarize the evidence on nutritional supplements in general for people with diabetes as follows: There is no clear evidence that supplementation with vitamins, minerals (e. g., chromium or vitamin D), herbs or spices (e. g., cinnamon or aloe vera) improves metabolic control in people without underlying nutritional deficiencies, and it is not generally recommended to improve glycemic control. Routine supplementation with antioxidants (e. g. vitamin E, C or carotene) is not recommended due to a lack of evidence of efficacy and long-term safety concerns. However, multivitamin supplementation may be necessary in special groups such as pregnant or lactating women, elderly individuals, vegetarians or people on an extremely low-calorie or low-carbohydrate diet [6]. Instead of the general recommendation of routine nutritional supplementation, people with diabetes should be encouraged to meet their nutritional needs through a balanced diet [8].

There is scientific evidence for supplementation with vitamin D, polyunsaturated fatty acids (PUFAs), chromium, zinc, magnesium, and iron especially for people with T1Dm.

For supplementation with PUFAs, a systematic review and meta-analysis summarizes data from 7 observational studies in subjects with preclinical and clinical T1Dm [100]. The evidence that PUFAs protect against preclinical T1Dm was classified as “low” when interventions were combined both during pregnancy and early childhood. However, a sub-analysis based on one study showed that supplementation with n-3 PUFAs in infancy could reduce the risk of preclinical T1Dm. Supplementation with PUFAs was not associated with a risk reduction for clinical T1Dm in children [100].

A cohort study based on 59 children with newly-manifested T1Dm and investigating the effects of a 12-month co-supplementation of n-3 PUFAs and vitamin D showed an improvement of surrogate parameters of endogenous insulin secretion in the group of co-supplemented children vs. children supplemented only with vitamin D in a reduction of the nutritive intake of arachidonic acid against the background of a Mediterranean diet [101].

In people with T1Dm, vitamin D is the most commonly studied nutritional supplement. Serum concentrations of vitamin D are lower in patients with T1Dm than in controls, but it is still unclear whether vitamin D deficiency is a trigger or consequence of autoimmune disease [102] [103]. The effects of vitamin D supplementation on the risk of T1Dm in young children have been investigated in 2 meta-analyses and one review, which partly overlap in the included studies [103] [104] [105]. There are insufficient studies on whether prenatal supplementation with vitamin D influences the risk of T1Dm later in life [103] [104]. Observational studies suggest that administration of vitamin D during infancy seems to be associated with a reduced risk of T1Dm [103] [104] [105]. A dose-response relationship could be subject to this relationship: a higher vitamin D intake is associated with a lower risk of T1Dm, and the timing of supplementation could also be critical, a lower risk of T1Dm was found at 7–12 months vs. 0 and 6 months of supplementation [105]. Two observational studies also suggest that vitamin D administration in young adults may have a protective effect on the risk of T1Dm [103]. The evidence from intervention studies and randomized controlled trials on the effect of vitamin D supplementation for the treatment of manifest T1Dm is summarized in one systematic review and two additional reviews. Even after that, the results are contradictory, and vitamin D supplementation only shows a protective effect on β-cell function and glycemic control in some studies [103] [106] [107]. With regard to vitamin D, the current recommendation may be that people with a high genetic risk for T1Dm should avoid vitamin D deficiency by adequate supplementation, but the evidence for the administration of higher doses of vitamin D is insufficient [106].

In a case-cohort study of 257 children with T1Dm, the question was investigated whether iron supplementation during pregnancy and the first 18 months of life is associated with an increased risk of T1Dm in childhood. It was concluded that maternal supplementation with iron is not associated with the risk of T1Dm, but that infantile supplementation shows an inverse association with the risk of T1Dm [108].

Serum concentrations of the trace elements chromium, zinc and magnesium are lower in persons with T1Dm compared to control persons. Observational studies show correlations between lower serum concentrations of these trace elements and poorer glycemic control in subjects with T1Dm, so supplementation may help improve metabolic control. However, further studies are needed to formulate a clear recommendation [109]. For the trace element zinc, a further systematic review, a meta-analysis, and a review were identified. The former comprises 25 studies, 3 of them with subjects with T1Dm. The 2 case-control studies show an increased zinc concentration in erythrocytes as well as reduced lipid peroxidation after zinc supplementation, and the randomized, double-blind study demonstrates an effect of zinc supplementation on lipid metabolism [110]. A review describes zinc supplementation as a possible measure to improve blood glucose control and lipid metabolism in individuals with T1Dm, but points to the need for further studies due to the conflicting results of existing human studies [111].

In summary, the evidence on the use of nutritional supplements in persons with T1Dm is heterogeneous and insufficient. The American and Canadian medical societies do not make a general recommendation on the use of nutritional supplements to improve metabolic control. Only compensating a nutritive vitamin D deficiency in persons with a high genetic risk for T1Dm could minimize this risk. A balanced diet generally provides an adequate supply of micronutrients.


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Probiotics

Recommendation

  • In view of the current study situation, no recommendation can be made for taking probiotics for the prevention or therapy of type 1 diabetes mellitus.


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Comment

In Germany, probiotics are specified as “defined living microorganisms which enter the intestine in an active form in sufficient quantity and achieve positive health effects” [112].

The Lactobacillus and Bifidobacterium genera are mainly used for the formulation in probiotics. Furthermore, specific lactic acid-producing species of other genera are used, e. g. Enterococcus faecalis, Streptococcus thermophilus or probiotic yeasts (Saccharomyces boulardii). The dose varies between 108 and 1011 colony forming units, and the use of the above genera or species is considered safe [113].

Probiotics are classified as nutritional supplements in Germany. The manufacturers are legally free to decide on the dose, strains used or any combination (multi-strain preparations) as well as possible additives (vitamins, prebiotics, etc.). Health claims or claims referring to the reduction of a disease risk are not permitted for probiotics, except for the improvement of lactose intolerance and the reduction of infections (EC 1924/2006).

The intestinal microbiome and the immune system are closely intertwined [114]. The immunomodulating effect of the intestinal microbiota or its metabolites, such as short-chain fatty acids, especially butyrate, is shown, among other things, by their effect on regulatory T cells [115] [116], the inflammatory status [115], and the function of the intestinal barrier [117]. In several studies of volunteers with diagnosed type 1 diabetes, microbial diversity was found to be lower than in healthy volunteers [118] [119] [120]. In the period immediately before or at the onset of beta-cell autoimmunity, a higher proportion of Bacteroides was repeatedly observed in the subjects compared to the control group [121] [122] [123] [124]. The lipopolysaccharide (LPS) produced by Bacteroides showed an immunosuppressive effect (measured by TLR4 and NF-κB activity) in children prone to autoimmune disease [125]. Current studies also suggest an association between reduced production of short-chain fatty acids, especially butyrate, by the microbiome, and an increased risk of type 1 diabetes [118] [124] [125]. This leads to the hypothesis that intestinal microbial disorders are associated with the pathogenesis of beta-cell autoimmunity and type 1 diabetes mellitus [127] [128].

To test the preventive effect of probiotics on the development of beta-cell autoimmunity, studies were conducted in genetically predisposed children before the onset of autoimmunity, primarily in infancy and early childhood [129] [130]. In the prospective, longitudinal, multicenter cohort “Environmental Determinants of Diabetes in the Young” (TEDDY), probiotic intake pre- and postnatally was assessed in 7473 infants/children with genetic predisposition to type 1 diabetes. Early infant (0–27 days postnatal) probiotic intake may reduce the risk of beta-cell autoimmunity in children with high-risk genotype (HLA-DR3/4) [129]. On the other hand, in a double-blind, randomized, controlled trial, the administration of probiotics in infancy could not be associated with the development of beta-cell autoimmunity [130].

In addition to preventive research on beta-cell autoimmunity, there are also studies on the effects of probiotics in already manifest type 1 diabetes. An eight-week supplementation of synbiotics (Lactobacillus sporogenes GBI-30 with maltodextrin and fructooligosaccharides) in 50 subjects (4–18 years old) with diagnosed type 1 diabetes resulted in an improvement in fasting blood glucose, HbA1c, hs-CRP and TAC (total antioxidant capacity) [188].

Another intervention study was conducted to determine whether a three-month supplementation with Lactobacillus rhamnosus GG leads to an increased immune function in type 1 diabetes patients following an influenza vaccination. No improvement in the humoral immune response was observed, but an anti-inflammatory effect was induced by supplementation [133].

The following points must also be considered when supplementing with probiotics: on the one hand, probiotics can exhibit antibiotic resistance in mobile genetic elements that can be transferred to other, possibly pathogenic bacteria through interbacterial exchange [134]. The investigation of various commercially-available probiotics showed that the probiotic bacteria tested were resistant to several different broad-spectrum antibiotics [135]. On the other hand, in rare cases, a weakened intestinal barrier function in critically-ill patients can lead to a translocation of the supplemented microorganisms [136]. In addition, possible side effects are not recorded in many studies in which the use of probiotics is tested.

Finding a causal relationship between intestinal microbiota and the pathogenesis of beta-cell autoimmunity is proving difficult. On the one hand, this is due to the high heterogeneity of the genera or species of probiotics used, the study populations as well as the study parameters; on the other hand, to the individuality and complexity of the microbiome. New findings also show that the administration of probiotics can significantly influence the efficacy of a probiotic by making it resistant to colonization by individuals, strains and regions, depending on the indigenous microbiome [137]. Overall, there is evidence to suggest that probiotic intake may be helpful in the prevention or therapy of islet autoimmunity and type 1 diabetes. However, in the current study situation, no recommendation can yet be made for taking probiotics for the prevention or therapy of type 1 diabetes mellitus.


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Conflicts of Interest

Diana Rubin: Lecture fees: DGVS and Kaiserin-Friedrich-Stiftung; Anja Bosy-Westphal: none; Stefan Kabisch: Fees and travel expenses by Sanofi, Berlin Chemie, Boehringer Ingelheim and Lilly; Travel expenses and research funding by J. Rettenmaier & Söhne, Holzmühle; further research funding by Beneo Südzucker and California Walnut Commission; Peter Kronsbein: none; Marie-Christine Simon: none; Astrid Tombek: none; Katharina Weber: none; Thomas Skurk: Lecture fees: Novo Nordisk

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Correspondence

Prof. Dr. med. Thomas Skurk
Technical University of Munich
ZIEL – Institute for Food & Health
Gregor-Mendel-Str. 2
85354 Freising
Germany   
Telefon: +49/81 61/71 20 07   
eMail: skurk@tum.de

Publikationsverlauf

Artikel online veröffentlicht:
13. Januar 2023

© 2023. Thieme. All rights reserved.

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

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