Yorkie Weight Loss Understanding the Link Between Diet and Behavior
Yorkie Growth & Weight Chart: Puppy to Adult (With Pictures)
Yorkies are wonderful dogs, but no one will ever accuse them of being big pups. These are tiny dogs, suitable for living in your lap or riding around in your purse.
Even so, many Yorkie owners inevitably find themselves wondering if their pup is normal in terms of size. Its understandable, as an overgrown Yorkie can be prone to health problems, while an undersized one may be malnourished.
With that in mind, weve prepared a guide that lets you know just how big do Yorkies get, along with how big Yorkies should be at various points of their development. There are always outliers, of course, so dont use this in place of a vets advice, but it should be useful as a broad guideline.
Yorkie Breed Overview
Yorkies are one of the smallest dog breeds on the planet, only tipping the scales at 37 pounds when fully grown. As a result, you may not see much change in their size from week to week or even month to month.
If anything, these charts may be more useful as indicators of whether your Yorkie is getting too big. Many people spoil these dogs, and they can often become overweight as a result. This is terrible for their health, so use the data below to make sure youre not overfeeding your pup.
Also, keep in mind that all this information is designed for purebred Yorkies. If you have a mix, that can skew the data significantly.
Yorkie Puppy Growth and Weight Chart
All the information below is a general estimate of where the average Yorkie will be at different stages of their development. As with humans, some Yorkies develop at different rates, and yours may be bigger or smaller than average at various points.
Therefore, you shouldnt panic if your dogs size doesnt correspond with the chart below in a single time window. Instead, track their growth over several weeks or months, and only start to become concerned if theres a consistent pattern of being too big or small.
Another important thing to realize is that one of the biggest factors affecting your dogs growth will be their birth weight. If they were huge at birth, theyll likely be bigger at every stage of development before ultimately becoming large adults. The opposite is true for very small newborns.
Yorkie Puppy Growth and Weight Chart (Male)
Weight Range Height Range 8 weeks 21.5 oz. 24 in. 9 weeks 23 oz. 24 in. 10 weeks 25 oz. 25 in. 11 weeks 28 oz. 35 in. 3 months 32 oz. 36 in. 4 months 40 oz. 47 in. 5 months 46 oz. 48 in. 6 months 51 oz. 59 in. 7 months 55 oz. 69 in. 8 months 58 oz. 79 in. 1 year 64 oz. 79 in. 2 years 64 oz. 79 in.
Yorkie Puppy Growth and Weight Chart (Female)
Weight Range Height Range 8 weeks 21.5 oz 24 in. 9 weeks 23 oz. 24 in. 10 weeks 25 oz. 25 in. 11 weeks 28 oz. 35 in. 3 months 32 oz. 36 in. 4 months 40 oz. 47 in. 5 months 46 oz. 48 in. 6 months 51 oz. 59 in. 7 months 55 oz. 69 in. 8 months 58 oz. 79 in. 1 year 64 oz. 79 in. 2 years 64 oz. 79 in.
You need to take good care of your pet while they are growing, so you can use our calculator tool to help you know how much to feed your pup and keep their well-being:
The exact amount of calories an individual animal needs to maintain a healthy weight is variable and influenced by many factors including genetics, age, breed, and activity level. This tool is meant to be used only as a guideline for healthy individuals and does not substitute veterinary advice
Yorkie Growth Stages
Like most small-breed dogs, Yorkies mature faster than their larger counterparts. That means you shouldnt compare them to, say, your neighbors Great Dane; however, if you do, youll likely notice that your dog goes through a few stages of growth more rapidly.
Below, we explain what you should look for at each stage, including major milestones, necessary vaccines, and how much your dog should be eating.
8-week-old (2 months) Yorkie
At 8 weeks, your Yorkie is ready to be weaned from their mother (this is also the week that you get to bring your new buddy home if youre adopting or buying from a breeder).
They should be eating an appropriate puppy kibble at this point, and you can let them free-feed. Just set a bowl of food out for them, and replenish it as necessary. Your dog is growing rapidly and needs all the calories that they can get.
Your puppy should get their first shots at this point, as they need boosters for parvo and distemper.
12-week-old (3 months) Yorkie
Once your Yorkie is 3 months old, you should stop free-feeding them and instead give them portion-controlled meals three times per day. How much you feed them will depend on the food and their size, but in general, they should receive between and a cup of food per day.
Your dog will need another round of parvo and distemper shots, and they should also receive a complete checkup at this point (including a stool sample).
By this point, they should be acclimated to your home (assuming that you brought them home at 8 weeks). You can also begin housetraining them and teaching them to walk on a leash.
6-month-old Yorkie
At 6 months old, your Yorkie should be their final color. Theyll also be close to their final size, although some Yorkies keep growing until theyre a year old.
If your pup has put on enough weight, you can likely start feeding them only two meals per day. You can keep the total amount of food the same or drop it down a bit, depending on the advice of your vet.
Its important to pay attention to your dogs bite at this stage as well, as its not uncommon for their jaws to suddenly become misaligned around 5 or 6 months old.
They should have a rabies vaccination at this time, and theyre also old enough to start learning more advanced obedience techniques. This is also when they reach sexual maturity, so you should have your dog spayed or neutered if youre not planning to breed them.
12-month-old (1 year) Yorkie
At 12 months, your Yorkie is now officially an adult. With your Yorkie at full-grown size, you can commemorate the occasion by switching them (slowly) to an adult dog food. Continue feeding them to cups of food daily in two servings, unless otherwise advised by your vet.
Theyll need a round of boosters at this stage, including rabies, DHPP, coronavirus, leptospirosis, Bordetella, and Lyme disease. They should also be on flea and tick medication and a heartworm pill.
You can do just about anything with a 12-month-old Yorkie, including putting them through advanced training classes and long grooming sessions. Theyll stay an adult until they turn 8 or so, at which point theyll be considered a senior dog.
When Do Yorkies Stop Growing?
Yorkies grow quickly (although they dont grow very much). Many Yorkies stop growing and are fully mature by the time theyre 6 or 8 months old, although some take until they turn a year old to reach physical maturity. As a general rule, though, if your Yorkie is still adding weight after theyve turned 1, its time for a diet.
They also mature quickly from a mental standpoint. You can start training a Yorkie earlier than you would a larger-breed dog, and theyll have the attention span and intelligence to handle advanced techniques by the time theyre 6 months old.
The flip side to this is that they lose their puppy-ness sooner than other dogs, but even adult Yorkies are still fairly puppy-like.
How Does Neutering/Spaying Affect My Dogs Growth?
Since Yorkies mature so quickly, spaying or neutering them has little effect on their growth. By the time theyre old enough for the procedure, theyll likely be close to their final size.
However, allowing your female Yorkie to become pregnant before theyre fully mature can stunt their growth a bit, as the nutrients that they need to continue growing will go to their puppies instead. If youre planning on breeding your dog, wed recommend waiting until theyre fully mature to do so.
Dangers of Growing Too Quickly or Stunted Growth
Its very rare for a Yorkie to grow too quickly or have their growth stunted. Keep in mind that youll find quite a few variations in size within the breed, so see if your vet says that you should be concerned.
If your Yorkie is packing on extra weight, though, you should decrease their caloric consumption and increase their exercise levels. Being overweight can lead to a host of different health conditions, including diabetes, heart disease, and joint problems.
However, if your dog isnt putting on any weight at all, you should take them in for a checkup. This is often a sign of an intestinal parasite, so the vet will likely want to take a stool sample to be sure.
If your Yorkie is way off the growth chart in both height and weight, it may indicate that theyre not purebred. Yorkie mixes can weigh 15 pounds or more, but its extremely rare for a purebred Yorkie to get anywhere near that big. If you bought your dog from a breeder, you might want to start asking questions.
Conclusion
Yorkies are wonderful dogs, and raising them as puppies can be both fun and challenging. Ideally, youll want your dog to grow slowly and steadily, but thats not always possible with this breed.
Dont be alarmed by sudden growth spurts, and dont be concerned if your dog stops growing at 6 or 8 months. These dogs mature quickly, and their puppyhood fades fast.
As long as your Yorkie isnt too much of an outlier (and as long as your vet isnt concerned with their growth), you have nothing to worry about. So, sit back, relax, and enjoy watching your new Yorkie grow to full size and explore the world.
Featured Image Credit: Pezibear, Pixabay
Diet, Stress and Mental Health
1. Introduction
The relationship between diet and behavior has long been a topic of interest. This includes the effects of diet on both mental and physical health, as well as related topics of the role of stress and obesity in these processes [1]. Dietary modification can prevent the development of cardiovascular disease (CVD) and diabetes [2], and stress-related mental disorders, including major depression and posttraumatic stress disorder (PTSD), are associated with an increased risk for CVD [3,4,5,6,7,8], although the mechanisms of these interactions are not well understood [9,10]. Specifically, there is a limited understanding of how diet affects mental health, and the way outcomes of unhealthy diet such as obesity interact with stress-related psychiatric disorders.
The relationship between these factors is often bidirectional. For example, changes in diet may influence psychiatric disorders through direct effects on mood, while the development of psychiatric disorders can lead to changes in eating habits [11]. shows the myriad and complex relationships that can exist between diet and psychiatric symptoms. In Path A in the figure, stress can act through the brain to cause an increase in over-eating [12], including binge-eating [13], and a reduction in exercise that in turn leads to obesity and/or metabolic syndrome (MetS, defined as increased blood pressure, and blood sugar, excess waist body fat and elevated cholesterol or triglyceride levels), which may in turn lead to disorders such as depression due to functional and/or social impairments [14]. In Path B, stress-related psychiatric disorders develop (PTSD, depression) that are associated with changes in metabolism and obesity [15]. Path C acts through physical disorders such as cardiovascular disease (CVD) and diabetes, that may come by way of PTSD and depression, and are related to those disorders in a bidirectional relationship or perhaps through shared pathways. Stress-induced over-eating leads to obesity, which in turn can be associated with changes in neurotransmitters, neuropeptides, and inflammatory factors that are present in both the gut and the brain and have effects on both mood and subsequent eating behaviors [16,17]. Path D shows the effects of neurotransmitters (e.g., serotonin) and neurohormones (cortisol), inflammatory factors are shown in Path E, and neuropeptides (ghrelin, galanin) reviewed below are shown in Path F. Finally, returning to Path A, changes in diet can affect the gut microbiome, which can have effects on mood, and is involved in a complicated bidirectional interaction between brain and inflammatory function as well as the abovementioned neurotransmitters and neuropeptides [18].
The complex relationship between diet, obesity and behavior. Stress acts through the brain to both affect eating and exercise behaviors (Path A) and stress-related psychiatric disorders including posttraumatic stress disorder (PTSD) and depression (Path B), both of which can lead to changes in metabolism, metabolic syndrome (MetS) and obesity (Paths A and B). Binary relationships also exist between unhealthy eating and PTSD/depression and the brain (i.e., both in turn lead to changes in brain function). Unhealthy eating can result in diets high in saturated fat (fatty food ingestion) (Path A) that can affect mood (dysphoria) as well as leakiness of the intestinal wall (Path A), which can lead to changes in the gut microbiome which modulate obesity, MetS and metabolism (Path A), as well as feeding back on the brain (Path A) to influence mood (dysphoria). Physical disorders including cardiovascular disease (CVD) and diabetes (Path C) and physical factors such as intra-abdominal fat (Path C) are affected by stress and related to PTSD and depression. A complex system of neurotransmitters (norepinephrine, serotonin, dopamine) (Path D), inflammatory markers (Path E) and neuropeptides (ghrelin, somatostatin, galanin) (Path F) present in the gut and brain are also influenced by stress via the brain, influence the gut microbiota and physical disorders and factors in a binary fashion and in turn regulate both feeding behavior and psychiatric disorders. Within the figure, the line color indicates the path, with dashed lines indicating primary pathways and solid lines indicating secondary pathways.
This paper reviews possible mechanisms by which diet and obesity can affect mental health and the brain, and the complex interplay between these different factors. We review the effects of diet on mood, with feelings of dysphoria or symptoms of depression most relevant within this context. Factors such as ingestion of fatty foods, as reviewed below, may impact feelings of dysphoria, which is relevant to the topic. Many studies reviewed below examined depressive symptoms in populations that are not suffering from psychiatric disorders, such as pregnant women, or looked at populations such as the elderly in the community at risk for nutritional deficiencies. These studies of depressive symptoms are to be differentiated from studies of populations that meet the criteria for major depression, which together with PTSD are more relevant to the practice of clinical psychiatry. Another relevant topic to effects of diet on mental health is the area of supplements and specific food products, including polyunsaturated fats (PUFAs), which have been the subject of a variety of clinical trials as both treatments and preventative agents for depression.
2. Materials and Methods
The literature was reviewed from 1980 through June of 2019 using PubMed and Psych info with keywords diet; obesity; stress disorders; posttraumatic; stress; depressive disorders; depression; inflammation; and polyunsaturated fatty acids. Relevant articles were reviewed and included here. We included both cross-sectional studies and cohorts (retrospective and prospective) that investigated the effects of diet on mood, including depression and dysphoria. This review focused on stress-related psychiatric disorders including major depression and PTSD, as defined in the Diagnostic and Statistical Manual (DSM-5) [19]. These are not the only two psychiatric disorders influenced by stress, of course, but they have been the focus of the bulk of the research on diet and stress, and related topics such as obesity and metabolism. Mental disorders are considered synonymous with psychiatric disorders, and, for the purposes of this review, refer to PTSD and depression, which are also referred to as stress-related psychiatric conditions or mental disorders, and mental health is considered as the absence of these conditions, again for the purposes of this review. Mood entails changes in emotions including depressed or sad emotions, or depressive symptoms, which may or may not be related to the DSM-5 diagnosis of major depression, but is referred to here as relevant to understanding the effects of stress and diet on behavior.
2.1. Effects of Diet on Health
In the past forty years, there has been a remarkable increase in worldwide obesity [20,21], which has been associated with an increase in type-2 diabetes and cardiovascular disease [22,23]. The increase in obesity is likely secondary to an expansion of the Western diet, which includes higher amounts of omega-6 relative to omega-3 fatty acids relative to other diets, largely through the substitution of carbohydrates in the form of grains for leafy plants, represented by ubiquitous processed foods [24]. Factors including an increase in perceived stress and a shift in the labor force from manual labor to sedentary occupations have also likely contributed to overeating (including binge eating) and the growth in obesity [2,25]. After a long period of no change, the prevalence of obesity in the United States doubled every decade in the 1980s and 1990s, and now one third of Americans are afflicted by obesity and another one third overweight [26]. Obesity is associated with a 44% increase in risk for myocardial infarction, with an even more important association with abdominal fat that further contributes to systemic inflammation [27,28]. From 2000 to 2010, the prevalence of type-2 diabetes increased by 46%, from 151 million to 221 million world-wide [29], with more recent estimates showing 442 million persons to be affected by type 1 and type 2 diabetes worldwide [30], an effect largely driven by obesity [31,32,33,34]. Ethnic Chinese who emigrated from their homes in China, where the prevalence of diabetes was 2%, to countries where Western diets were more prevalent, such as Mauritius, experienced an increase in diabetes prevalence to 15% [29]. Modification of diet can reduce risk of diabetes [35] and cardiovascular disease [36].
One dietary approach that has been particularly well researched is the Mediterranean diet. This diet is rich in nuts, vegetables and fruit, and low in meat, with moderate consumption of red wine, and substitutes of unsaturated fats (olive oil) for saturated and monounsaturated fats (butter, animal fat). Originally described in Italians living in the countryside, the diet was noted to be associated with long life spans and low rates of cardiovascular disease. Studies have confirmed that the Mediterranean diet is associated with sustained weight loss [37], with a beneficial effect on cardiac autonomic function, reductions in peripheral inflammation, and reduced rates of cardiovascular disease, stroke, cancer, and mortality [1,37,38,39,40,41]. The beneficial effects of diet on health have led to speculation that diet modification may be beneficial for symptoms of depression.
2.2. The Influence of Diet on Mood and Psychiatric Disorders
The relationship between diet and mental disorders is complex. Studies have shown an increase in depression in obese individuals [14,42,43] that is greater in the presence of MetS [14]. As outlined above, stress can lead to an increase in overeating [16,44,45,46], obesity [12,47,48,49,50] and psychiatric disorders, including PTSD and depression [15]. Depression in obese individuals may be due to psychological issues related to self-consciousness about appearance, common factors such as a history of childhood abuse [12,47,48,49,50], or factors such as diet-induced changes in the gastrointestinal microbiome with effects on the brain [51,52]. Early trauma associated with obesity in adulthood is likely due to a resetting of metabolism, independent of changes in eating habits related to dysphoria and other emotional disturbances [12,53]. Binary relationships also exist between these variables as well; for instance, stress causes changes in eating habits, leading to obesity and MetS, which in turn can exacerbate depression.
Diet can also have direct effects on mood. The effect of diet on brain function is one pathway through which diet can affect mood and the development of psychiatric disorders [42,43,44,45]. Fats are known to interfere with the synthesis of serotonin, a key brain neurotransmitter implicated in the development of depression, while proteins have the opposite effect [42]. Therefore, a high fat diet has been hypothesized to cause mood disorders (while a low-fat diet would have the opposite effect) [54]. Research studies have in fact shown that high fat foods can lead to transient changes in mood [55], possibly via signaling of gut flora that is perceived by the brain [45]. Intake of fats leads to feelings of sleepiness that are not related to the food alone [56,57]. Uncontrolled observational studies have shown a reduction in fats in the diet in depressed patients who have a resolution of depression [58] and a relationship between symptoms of anxiety and depression, and a low carbohydrate, high fat diet [59]. Survey studies showed that patients consuming a diet similar to the Mediterranean diet had a reduced risk for the development of depression [60]. In summary, the relationship between diet, stress and psychiatric disorders is complex and likely bidirectional, with diet affecting psychiatric symptoms and psychiatric symptoms affecting diet with interactions with stress and obesity.
Studies in populations without the diagnosis of depression on the effects of dietary interventions have been mixed [11,61]. Although some studies showed a reduction in depressive symptoms in healthy insurance company employees with a vegan diet [62], elderly persons at risk for malnutrition [63,64], and women with breast cancer [65] with nutritional interventions and/or diets, other studies in healthy subjects showed no effects of a low carbohydrate high fat compared to a high carbohydrate low fat diet [66] or a low-fat diet versus no intervention [67]. Studies of dietary interventions with and without exercise training aimed at weight loss for obese and overweight individuals have in general shown improvements in well-being and quality of life without clinically significant reductions in symptoms of depression [68,69,70,71]. Similarly, studies of the Mediterranean diet did not show a reduction in symptoms of depression in populations without the clinical diagnoses of depression, although there were improvements in factors such as quality of life or self-reported vigor in some studies [72,73,74,75,76,77].
Studies have looked at the effects of dietary interventions in patients with depression. Two studies included veterans identified as having some symptoms of depression and exposure to psychological trauma who were randomized to a diet education group or problem-solving therapy (PST). In one sample, treatment with PST was associated with greater improvement in mental health as measured with the SF-36 with no difference between groups in depressive symptoms measured with the Beck depression inventory (BDI) [78]. A second study with a similar sample failed to find an improvement in depression with diet training [79]. The Supporting the Modification of lifestyle in Lowered Emotional States (SMILES) trial was performed in patients with clinical depression. In this study, a modified Mediterranean Diet intervention was associated with improvement in depression as measured with the Montgomery Asberg Depression Rating Scale (MADRAS) compared with a social support intervention which matched the number and length of visits [80].
In addition to depression, recent studies suggested a relationship between sleep duration and Mediterranean Diet. In the MESA Sleep ancillary study, a higher adherence to a Mediterranean-type diet was associated with a 43% greater likelihood of achieving 67 h of sleep per night compared to 6 h [81]. Data from the Seniors-ENRICA and Hellenic Longitudinal studies also found a lower likelihood of poor sleep quality for those who were following a Mediterranean diet [82,83]. Finally, a study performed in France showed that adherence to a Mediterranean diet predicted reduced risk of insomnia [84].
In summary, there is not strong evidence for an effect of dietary intervention on symptoms of depression, although effects are possible in patients with the clinical diagnosis of depression.
2.3. Diet Interventions for Depression
The use of dietary supplements for the treatment of depression has been the subject of intensive investigation [11] (). Omega-3 polyunsaturated fatty acids (n-3 PUFAs) are highly concentrated in fish oil, especially from mackerel, salmon, herring and sardines. (n-3 PUFAs)contain more double carbon bonds than saturated fats, such as butter and animal fats, and are more likely to be solid than liquid at room temperature. n-3 PUFAs, including eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA), have beneficial effects on health, including reduction in cardiovascular disease risk, improved cognition, enhancement of neuroplasticity, and protection against neuronal injury [85,86,87,88,89]. n-3 PUFAs are included in the category of eicosanoids, which bind to intra-nuclear receptors and regulate gene transcription, making them part of the nuclear receptor superfamily, which includes steroids, thyroid hormone, and retinoids, all of which have been linked to neuropsychiatric syndromes [90]. These studies suggested that n-3 PUFAs may have benefit in the treatment and/or prevention of depression.
Table 1
Controlled Trials on Dietary Interventions for Depression.
| Author-Year | Study | Population | Intervention | Sample | Outcome measure | Result | |
|---|---|---|---|---|---|---|---|
| Agarwal 2015 | GEICO | Healthy employees | Vegan diet v no intervention | Randomized (n = 292) | SF-36 |  | depression, anxiety, QOL |
| Almeida 2014 | B-VITAGE Adjunctive to antidepressants | Major depression >age 50 | VB6/VB12/Fol v Pla | Randomized (n = 153) | MADRS |  | relapse, MADRS NS |
| Andreevna 2012 | SU.FOLOM3 | CAD patients | EPA/DHA v placebo | Randomized (n = 2501) | GDS | NS depression | |
| Assaf 2016 | WHI Study | Women | Low fat diet v no intervention | Randomized (48,835) | CES-D | NS depression | |
| Bedson 2014 | FolATED Adunctive to antidepressants | Patients with depression | Fol v pla | Randomized (n = 475) | BDI, MADRS | NS depression | |
| Bot 2010 | Patients with MDD & Diabetes | EPA v placebo | Randomized (n = 25) | MADRAS | NS depression | ||
| Carney 2009 | Adjunctive to antidepressants | Patients with CAD & depression | DHA/EPA v placebo | Randomized (n = 122) | HDRS, BDI | NS depression | |
| Carney 2019 | Adjunctive to antidepressants | Patients with CAD or hi risk & depression | EPA v placebo | Randomized (n = 144) | HDRS, BDI | NS depression | |
| Coppen 2000 | Adjunctive to antidepressants | Major depression | Fol v pla | Randomized (n = 127) | HDRS | | depression |
| Da Silva 2008 | Adjunct antidepressants | Patients with PD & depression | Fish oil v placebo | Randomized (n = 31) | MADRAS, BDI | | MADRS depression, BDI NS |
| De Koning 2016 | B-PROOF | Community sample, older adults | Fol/VB12 v pla | Randomized (n = 2,919) | GDS | NS depression | |
| Doornbos 2009 | Pregnant women | EPA/DHA v placebo | Randomized (n = 119) | EPDS | NS depression | ||
| Endevelt 2011 | Israel | Elderly at risk for malnutrition | 5 visits with dietician & MD v booklet v nothing | Randomized (n = 127) | GDS | | Depression with dietician & MD |
| Einvik 2010 | Oslo Diet & Antismoking Study | Patients with hyperlipidemia | n-3 PUFAs v placebo v dietary counseling | Randomized (n =563) | HADS | NS depression | |
| Forster 2012 | UK | Elderly in community | Diet intervention v supplement v placebo | Randomized (n = 217) | GDS | NS depression | |
| Freeman 2008 | Adjunctive to therapy | Perinatal MDD | DHA/EPA v placebo | Randomized (n = 51) | HDRS | NS depression | |
| Garcia Toro 2016 | Adjunctive to antidepressants | Patients with depression | Med Diet adherenec | Observational (n = 273) | BDI | NS depression | |
| Gharekhani 2014 | Hemodialysis patients with depressive symptoms | DHA/EPA v placebo | Randomized (n = 54) | BDI | | Depression | |
| Gertsik 2012 | Adjunctive to antidepressants | Patients with depression | Citalopram + EPA/DHA/O3FA v Cit + pla | Randomized (n = 46) | HDRS | | depression |
| Grenyer 2007 | Adjunctive to antidepressants | Patients with depression | DHA/EPA (fish oil) v placebo | Randomized (n = 83) | HDRS, BDI | NS depression | |
| Halyburton 2007 | Overweight or Obese patients | Low carb high fat v high carb low fat diet | Randomized (n = 93) | POMS, BDI | | Weight in both groups, cognition low fat, NS depression | |
| Hyypa 2003 | Men with hyper- cholesterolemia | Simvistatin v Med Diet v placebo | Randomized (n = 120) | BSI |  | NS depression | |
| Imayama 2011 | Obese and overweight post-menopausal women | Weight loss diet, exercise v no intervention | Randomized (n = 439) | BSI | | Depression diet/exercise, NS depression diet alone | |
| Jacka 2017 | SMILES study | Patients with clinical depression | Med. Diet v Social Support | Randomized (n = 67) | MADRAS | | Depression |
| Jazayeri 2008 | Patients with clinical depression | Flu + EPA v flu + pla v EPA + pla | Randomized (n = 60) | HDRS | | Depression | |
| Jenkinson 2009 | Obese patients with knee pain | Diet v exercise v no intervention | Randomized (n = 389) | HADS | | Depression | |
| Kasckow 2014 | Veterans with symptoms of depression | Diet Education Group v PST | Randomized (n = 45) | BDI, SF-36 | | NS depression,GMH | |
| Kasckow 2014 | Veterans with symptoms of depression | Diet Education Group v PST | Randomized (n = 60) | BDI | NS depression | ||
| Kwok 2019 | Older MCI+ H-Hcy | VB12/fol v pla | Randomized (n = 279) | CDR, HDRS | | Depression | |
| Llorente 2003 | Obese and overweight post-menopausal women | DHA v placebo | Randomized (n = 439) | BSI | NS depression | ||
| Lesperance 2011 | Patients with depression | EPA/DHA v placebo | Randomized (n = 432) | IDS | NS depression | ||
| Llorente 2003 | Pregnant women | DHA v pla | Randomized (n = 99) | BDI | |||
| Lucas 2009 | Middle aged women with symptoms of depression | EPA/DHA v pla | Randomized (n = 120) | HDRS | NS depression | ||
| Makrides 2010 | DOMInO study | Pregnant women | DHA v pla | Randomized (n = 2399) | EPDS | NS depression | |
| Marangell 2003 | Patients with depression | DHA v placebo | Randomized (n = 36) | MADRAS | NS depression | ||
| McMillan 2011 | Young healthy women | Med Diet v no intervention | Randomized (n = 25) | POMS | | NS depression, cognition. vigor | |
| Mech 2016 | MDD+ MTHFR | VB6/VB12 v pla | Randomized (n = 330) | MADRS | | depression | |
| Mischoulon 2009 | Patients with depression | EPA v placebo | Randomized (n = 35) | HDRS | NS depression | ||
| Mischoulon 2015 | Patients with depression | EPA v DHA v placebo | Randomized (n = 196) | HDRS | NS depression | ||
| Mozaffari-Khosravi 2013 | Patients with depression | EPA v DHA v placebo | Randomized (n = 81) | HDRS | | Depression EPA, DHA NS depression | |
| Mozurkewich 2013 | The Mothers, Omega-3 and Mental Health Study | Pregnant with symptoms of depression | EPA Fish oil v DHA fish oil v placebo | Randomized (n = 118) | BDI | NS depression | |
| Nemets 2002 | Adjunctive to antidepressants | Patients with MDD | EPA v placebo | Randomized (n = 20) | HDRS | | Depression |
| Nemets 2006 | Children with depression | EPA/DHA v placebo | Randomized (n = 28) | CDI, CDRS | | Depression | |
| Nieman 2000 | Obese women | Exercise and/or weight loss diet v wait list | Randomized (n = 91) | POMS | NS depression | ||
| Okereke 2015 | WAFACS | Normal women | VB6/VB12/Fol v pla | Randomized (n = 4331) | Clin dx | NS depression | |
| Peet 2002 | Adjunct to TAU | Patients with MDD | EPA v placebo | Randomized (n = 70) | HDRS, MADRAS | | Depression |
| Poppitt 2009 | Patients with Ischemic Stroke | Fish Oil with O3FA v pla | Randomized (n = 102) | GHQ | NS depression | ||
| Rees 2008 | Perinatal MDD | DHA/EPA (fish oil) v placebo | Randomized (n = 26) | HDRS, MADRAS | NS depression | ||
| Rondanelli 2010 | Elderly women with depression | DHA/EPA v placebo | Randomized (n = 46) | GDS | | depression | |
| Scheier 2005 | Young Women with Breast Cancer | Nutrion group v Health Ed v TAU | Randomized (n = 252) | CES-D | | Depression with nutrition group | |
| Serrano Ripoll 2015 | Primary Care Patients | Diet & exercise instructions v control | Randomized (n = 273) | BDI | NS depression | ||
| Silvers 2005 | Patients with MD in treatment | EPA/DHA (Fish oil) v placebo | Randomized (n = 77) | HDRS | NS depression | ||
| Sinn 2012 | Patients with MCI | DHA v EPA v linoleic acid | Randomized (n = 50) | GDS | | Depression | |
| Stoll 1999 | Patients with Bipolar Disorder | EPA/DHA (Fish oil) v placebo | Randomized (n = 30) | Time to relapse (clinical) | Delayed relapse | ||
| Su 2003 | Adjunct to TAU | MDD | EPA/DHA v placebo | Randomized (n = 28) | HDRS | | depression |
| Su 2008 | Pregnant women with MDD | EPA/DHA v placebo | Randomized (n = 36) | HDRS | | depression | |
| Su 2014 | Interferon patients | DHA or EPA v placebo | Randomized (n = 162) | Mini | | Depression onset | |
| Tajalizadekhoob 2011 | Adjunct to TAU | Elderly with mild to mod depression | EPA/DHA (Fish oil) v placebo | Randomized (n = 66) | GDS | | depression |
| Tayama 2019 | Patients with mild to mod depression | EPA/DHA v placebo | Randomized (n = 90) | BDI | NS depression | ||
| Toobert 2007 | Med Lifestyle Program | Postmenopausal women with DM2 | Med Diet & exercise v control | Randomized (n = 279) | CES-D | NS depression or QOL | |
| Wardle 2000 | Patients with hyper- cholesterolemia | Low fat v Med Diet v wait list | Randomized (n = 176) | BDI, POMS | NS depression |
Patients with depression have an increase in inflammation [91,92,93] and n-3 PUFAs have an inhibitory effect on this system, which suggests another potential beneficial effect for this disorder [94]. Inflammasomes are multi-protein complexes that detect signals in the inflammation pathway and activate pro-inflammatory cytokines [95]. Danger-associated molecular patterns (DAMPs) induced by stress are recognized by pattern-recognition receptors (PRRs), which trigger production of interferon alpha and beta and pro-inflammatory cytokines. Families of PRRs that are components of the inflammasome complex include nucleotide-binding domain, leucine-rich repeat containing proteins (NLRs, or NOD-like receptors). These induce caspase-1 and the inflammatory response and play a role in diseases involving inflammation [96], including PTSD and depression [92,97]. Specialized proresolving mediators (SPMs), including resolvins, lipoxins, maresins, and protectins, act as brakes on the inflammatory response and are released at the time of the initial inflammatory response [98,99,100]. Resolvins D1 and D2, derived from DHA, act through the mammalian target of rapamycin complex 1 (mTORC1) in the medial prefrontal cortex and hippocampus to mediate anti-inflammatory and antidepressant effects [101,102]. Similar effects are seen with resolvins E1 and E2, which are derived from EPA [103,104]. Studies showed an increase in the inflammasome NLRP3 and caspase-1 in blood cells of patients with major depression, with associated increases in interleukin 1 (IL-1) and IL-18, which correlated with depression severity [105]. NLRP12 was also found to be increased in Vietnam veterans with depression and coronary artery disease (CAD) [106]. Other studies showed an increase in myeloperoxidase [107].
Patients with depression also show alterations in endogenous n-3 PUFAs that may be linked to inflammatory alterations in these patients [11,54]. Patients with depression had higher blood concentrations of omega-6 relative to omega-3 fatty acids compared to individuals without depression [108], and depressed patients with low DHA and an elevated omega-6/omega-3 ratio in blood had an increased risk for suicide [109]. Elevated baseline inflammatory cytokines in patients with major depression predicted both risk for MetS [110] as well as a positive response to PUFA treatment for depression [94]. These studies suggested a complex but potentially relevant relationship between depression, inflammation, and n-3 PUFAs.
Studies have looked at n-3 PUFAs delivered as fish oil or DHA and EPA in comparison to placebo in several at risk non-depressed populations (). Hemodialysis patients randomized to a combination of DHA and EPA or placebo showed a significant reduction in depressive symptoms as measured with the BDI after four months [111]. EPA, but not DHA, resulted in a significant reduction in the number of patients who developed depression following treatment with interferon alpha for hepatitis C compared to placebo, although both EPA and DHA resulted in a significant delay in the onset of depressive symptoms [112]. DHA and/or EPA has not been found to result in significant decreases in symptoms of depression in patients with a history of ischemic stroke [113], mild cognitive impairment (MCI) [114], hyperlipidemia [115], or CAD [116,117]. Similarly, administration of DHA and/or EPA to pregnant and/or postpartum women did not result in a decrease in symptoms of depression [118,119,120,121]
Clinical trials of n-3 PUFAs have been conducted in patients with the diagnosis of depression. Randomized treatment with n-3 PUFAs in the form of fish oil, EPA and/or DHA compared to placebo showed a reduction in symptoms in patients with depression [11,54,92,107,122,123,124,125,126,127,128,129,130,131,132,133,134,135,136,137,138]. Patients with major depression and elevations in inflammatory biomarkers showed a stronger response to EPA (but not DHA) treatment compared to depressed patients without elevations in inflammatory biomarkers [94]. Other studies, however, did not show improvement in patients with depression [127,136,139,140,141,142,143,144,145]. Two studies of DHA and/or EPA added to the antidepressant sertraline in patients with depression and CAD or at risk for CAD showed no improvement compared to sertraline plus placebo [146,147]. Overall, studies are suggestive if not definitive, with a pattern of greater effect for EPA, especially when used as an adjunct to antidepressants, and in patients with more severe depression and/or biomarkers such as elevated inflammation.
Homocysteine is another dietary component that has been studied in relation to depression. Homocysteine is a sulfur-containing amino acid that is involved in carbon transfer reactions and is part of the B-12 and folate metabolic pathway [148]. Homocysteine can receive a methyl group from 5-methyltetrahydrofolate and become re-methylated to methionine, the immediate precursor of S-adenosylmethionine (SAMe), a donor of methylation reactions involved in the synthesis of DNA, proteins, phospholipids, neurotransmitters and polyamines relevant to depression, including dopamine, norepinephrine and serotonin in the brain. Some studies have shown efficacy for SAMe in the treatment of depression [149].
Elevated homocysteine concentrations can result from folate or B12 deficiency. Several studies have found a relationship between elevated homocysteine levels and/or low folate and B vitamins and depression [150,151,152]. Diets deficient in folate and vitamins B6 and B12 are also associated with depression [153]. Since the Mediterranean diet is rich in folate and B12, it could possibly reduce the risk of depression through correction of this nutritional deficiency. Consistent with this, adherence to the Mediterranean diet was associated with a reduction in circulating levels of homocysteine [154].
Studies in patients with depression supported a link between elevated homocysteine and low folate and Vitamin B12 and depression. Low baseline folate and vitamin B12 [155] and elevated homocysteine [155,156] predicted subsequent development of depression, and elevated homocysteine correlated with a past history of depression in men (but not women), even after adjusting for health-related behaviors [157]. Low folate (but not low vitamin B12 or elevated homocysteine) has been shown to be a predictor of poor response to antidepressants [158,159,160,161], as well as risk of relapse, in patients with depression [159]. Treatment with folate and/or vitamin B12 in patients with elevated homocysteine compared to placebo in healthy older adults resulted in significant decreases in homocysteine [162,163], but no improvement in cognition [162] or symptoms of depression [163,164] (). Long-term supplementation with folate and vitamin B12 did not prevent the development of depression in healthy women [165]. Studies in patients with depression showed that folate and/or Vitamin B12, including as an augmentation to antidepressants, resulted in improved symptoms of depression in some studies [166,167,168,169,170] but not others [164,171,172]. Greater reductions in depression were seen in depressed patients with the MHTFR polymorphism [167,173]. Supplementation of antidepressants with folate and/or vitamin B12 in one study reduced the risk of relapse after successful remission [172]. Not all studies, however, have found an association between homocysteine and depression [174,175,176,177,178,179]. The population-based Rotterdam Study found an association between depression and homocysteine; however, the association was reduced after controlling for cardiovascular disease and functional disability [152]. These inconsistent results may be due to factors such as variations in diet and vitamin supplementation, which can affect folate intake, which influences homocysteine concentrations.
The Dietary Inflammatory Index has been developed in recent years to characterize an individuals diet on a continuum from anti- to pro-inflammatory. Numerous studies investigating the role of Dietary Inflammatory Index on depression [180,181,182,183]. Results from the Whitehall II Study show a positive association between this index and recurrent depressive symptoms in women but not men [181]. Similar findings were observed in the Australian Longitudinal Study on Womens Health, where women with the highest inflammatory diet had an approximately 20% higher risk of developing depression compared to those with the lowest pro-inflammatory diet [180]. In another cohort study of 15,093 university graduates, participants in the highest quintile of Dietary Inflammatory Index were found to have a 47% increased risk of developing future depression compared to those in the lowest quintile [182].
Studies on the relationship between diet and depression have limitations. Many of the studies reviewed above and in involve populations without clinical depression and have considerable variability from study to study. Although it can be argued that some of these groups should be the subject of study because of potential risk for the development of depression, such as pregnant women, or patients with stroke, cancer, renal failure, CAD or MCI, they do not have equivalent relevance to the practice of clinical psychiatry as patients with the current diagnosis of major depression. Overall, findings from these studies suggest that although diet and/or supplements such as PUFAs may enhance vigor or quality of life, there is limited evidence for the prevention of or reduction in the development of symptomatic depression. Studies that did report positive results in non-clinical samples also had important limitations. For instance, the study of employees of an insurance company (the GEICO study) randomized to a vegan diet versus control used a design where group assignment occurred at company sites rather than on an individual level, so one company site was having regular meetings with dieticians, which were presumably discussed amongst employees, while the other site received nothing. Additionally, the study involved healthy individuals, used a measure not validated as a measure of clinical depression, and was performed by an advocacy group whose mission includes promotion of a plant-based diet [62]. Similarly, in a study of women with breast cancer, a dietary intervention induced a reduction in depression that was related to a one-point mean change in a 30-point scale (CES-D), with no change in mental health function, which although statistically significant, was of questionable clinical significance [65]. Obese patients with knee pain assigned to diet or exercise or no intervention showed a statistically significant improvement in depression measured with the Hospital Anxiety and Depression Scale (HADS). The improvement, however, was less than one point on a 21-point scale, which again was of questionable clinical significance [70]. Another study in obese and overweight post-menopausal women randomized to weight loss diet and/or exercise versus no intervention showed an improvement in depression as measured with the Brief Symptom Inventory (BSI) in the exercise and diet group, but not in the diet alone group [184]. These effects did not reach significance after correction for multiple comparisons, however, and involved a 1.7-point change in the BSI (4% change from baseline) of questionable clinical significance. EPA, but not DHA, resulted in a significant reduction in the number of patients who developed the diagnosis of depression as measured with the Mini following treatment with interferon alpha for hepatitis C compared to placebo, although both EPA and DHA resulted in a significant delay in the onset of depressive symptoms. Neither resulted in a significant reduction in depression compared to placebo on the Hamilton Depression Rating Scale (HDRS) [112]. Therefore, it can be seen that in non-clinical studies, most failed to show an effect of dietary intervention on depression, and if they did it was of questionable clinical significance. Studies in patients with the clinical diagnoses of depression also suffered from limitations. The Supporting the Modification of lifestyle in Lowered Emotional States (SMILES) trial was performed in patients with clinical depression. A modified Mediterranean diet intervention was associated with improvement in depression, as measured with the MADRAS compared to a social support intervention which matched the number and length of visits [80]. This study was criticized, however, for using recruitment materials implying a belief in the positive effects of diet on depression, including ads that had pictures of men made out of fruits [185]. This criticism is similar to that of the GEICO study, in that a bias for dietary change over medications may have been a confounding factor. In fact, nationalistic or cultural biases need to be considered as well. For example, we organized a conference on Mediterranean diet in conjunction with a Southern European country, who presented us with a giant round of Pecorino Romano cheese courtesy of their governments office for the promotion of national products. Similarly, findings supporting beneficial effects of an Indian diet fell apart after publication in The Lancet, when a site visit to the study location revealed only a few broken electrocardiogram machines in an abandoned building in the jungle and the claim that the original data from the study had been eaten by termites [186]. Even in the absence of financial or cultural bias, opinions run strong on the subject of diet and depression. For instance, a meta-analysis found no significant effect of PUFAs on depression after adjusting for possible publication bias, and concluded that positive effects were limited to small studies [187]. This paper was met with another meta-analysis that strongly disputed these conclusions [131]. There have in fact been a large number of meta-analyses, mostly concluding a positive effect for PUFAs on depression [131,132,133,134].
Although specific foods may have short-term effects on mood, overall the findings are equivocal for clinically significant effects of diet on mental health. Evidence for a link between obesity and depression is also inconsistent. Replicated findings in fact show a stronger link for MetS than obesity with depression [14,34]. It is questionable whether research on the effects of diet on mental health can be adequately controlled given the high expectancy bias for the effects of diet on mood, the inability to mask the nutrition interventions, and the psychosocial impact of multiple meetings in groups devoted to education about health and diet [185]. Effects of n-3 PUFAs on patients with the clinical diagnosis of depression are stronger. In fact, the American Psychiatric Association now recommends intake of 500 mg of omega-3 fatty acids per day in the diet for patients with depression.
2.4. Neurotransmitters and Neuropeptides Affected by Diet, Obesity and Psychiatric Disorders Related to Stress
Alterations in neurotransmitters and neuropeptides that are involved in stress, psychiatric disorders and/or appetite represent a possible mechanism by which stress may increase the risk of obesity and form a link between diet and stress-related psychiatric disorders. Tissues in the brain and the gut are both derived from ectodermal cells in fetal development, and share signaling pathways in common that can provide a link between stress, diet, obesity, and psychiatric disorders, including neurotransmitters (Pathway D in ) and neuropeptides (Pathway F in ). Serotonin is a neurotransmitter present in the brain and the gut that regulates a wide variety of relevant behaviors and physiological functions, including the regulation of anxiety, arousal, vigilance, aggression, mood, impulsivity, sleep, and food intake, as well as physical functions including cardiovascular, respiratory, motor output, neuroendocrine secretion, and analgesia [188,189]. Stress is associated with alterations in serotonin function in the medial prefrontal cortex and other brain areas involved in the stress response [190,191] and altered serotonin function is associated with both depression and PTSD [192,193]. Cortisol plays a critical role in stress, is altered in PTSD, and is associated with increased deposition of intraabdominal fat [194]. Norepinephrine release in the brain is an important part of the behavioral response to stress [195,196]. The majority of norepinephrine cell bodies are located in the brain stem, in the locus coeruleus region of the pons, with axons that extend throughout the rest of the brain, and are activated by stress, leading to fear and anxiety behaviors [197,198,199,200,201,202,203,204]. Alterations in noradrenergic and peripheral sympathetic function play a role in the maintenance of symptoms of both depression and PTSD [193,195,196,205,206]. Norepinephrine also plays an important role in feeding behavior [207]. Dopamine is a neurotransmitter that is involved in a number of functions including the control of locomotion, cognition, affect, neuroendocrine secretion, reward systems including feeding behavior, and the stress response [208,209,210]. Dopaminergic innervation of the nucleus accumbens, the mesolimbic pathway, regulates feelings of pleasure, and deficits in this system could underlie feelings of a lack of pleasure or anhedonia in patients with stress-related psychiatric disorders [210]. Mesolimbic dopamine also underlies the rewarding properties of food and drives food seeking behaviors, although additional brain regions are also involved in this process [208].
Neuropeptides are another potential link between stress, diet and psychiatric disorders. Somatostatin is the major inhibitor of growth hormone (GH) secretion in the brain and is located in the paraventricular nucleus (PVN) of the hypothalamus, the amygdala, hippocampus, cerebral cortex, median preoptic area, nucleus accumbens, and other areas of the brain [211]. Somatostatin inhibits extinction, modulates sleep, food intake, locomotor activity, and memory function [212] and increases in response to stress [213]. Increased somatostatin levels in the CSF were seen in patients with PTSD [214]. Galanin is a peptide concentrated in brain areas involved in the stress response that mediates a number of physiological and behavioral functions, including learning and cognition, pain control, food intake, neuroendocrine control, and cardiovascular regulation, as well as depression and anxiety [215,216]. Alterations in galanin have been hypothesized to underlie depression [215,216]. Ghrelin is a peptide synthesized in the stomach and pancreas that is involved in the regulation of appetite and food digestion. Ghrelin levels rise before meals and stimulate food intake, and alterations in ghrelin function have been linked to obesity [217]. Stress increases ghrelin levels in the plasma [218,219], and ghrelin mediates the stress-induced increase in food intake associated with exposure to chronic stress [220] as well as behavioral responses to stress [219]. Ghrelin crosses the bloodbrain barrier, where it acts through ghrelin receptors to stimulate the release of growth hormone in the basolateral nuclear of the hypothalamus and the amygdala, where it enhances fear learning with chronic stress [221]. In summary, a number of neurotransmitters and neuropeptides that are located in both the brain and the gut and that mediate both stress and feeding behaviors may be the link between stress, diet and stress-related mental disorders.
2.5. The Gut-Brain Connection
Recently, the role of the gastrointestinal microbiome in affecting brain function has been recognized, with possible implications for the development of mental disorders in the context of diet and metabolism [18,52]. The gastrointestinal flora is composed of a range of bacterial species that have beneficial effects for our digestion and other functions; these are also affected by factors such as stress and a high fat diet [222,223,224] and influence brain function through the release of various signaling molecules. Additionally, they interact with neurotransmitters and neuropeptides reviewed in the prior section, which can lead to changes in mood and stress reactivity [45,224,225,226,227]. High fat diets can lead to leakiness of the gut epithelium, resulting in the release of inflammatory factors and penetration of gut flora in the intestinal wall, which can further increase the risk of depression via alterations in signaling pathways leading to the brain [51,227,228]. Studies have shown that the gut biota can influence both risk for MetS, and via gut biota that synthesize a metabolite of dopamine risk for depression [229,230]. Studies have looked at the effects of the replacement of the bacterial flora with probiotics or other agents for the treatment of mood disorders, with some success [229,231]. In conclusion, the gut microbiome interacts with diet and the environment to affect mental disorders in complex ways that are imperfectly understood but represent a promising area for future research and possible interventions.
3. Conclusions
The relationship between diet, obesity, stress, and stress-related psychiatric disorders is complex. Overall, there appears to be a link between diets low in saturated fats and high in omega-3 polyunsaturated fats and reduced risk of both obesity, MetS and stress-related psychiatric disorders, as well as beneficial effects for other health outcomes. This favors a diet that is rich in fruits, nuts, and vegetables, and fish, as is seen in the Mediterranean diet. Specifically, fish oils are a rich source of omega-3 fatty acids, and likely have a beneficial effect on mental and physical health. There are a number of potentially confounding factors, however, such as increased healthy behaviors in those who adhere to specific diets that could contribute to a spurious association. Most studies have focused on dietary interventions such as fish oils or PUFAs in the treatment of depression or the prevention of symptoms of depression in at risk groups. There is not good evidence for dietary interventions for at risk groups, and given the enthusiasm for diet as an intervention, the possibility of confirmation bias cannot be ruled out.
Although a Mediterranean diet, in combination with other behavioral changes, was found to have beneficial effects on perceived stress and well-being, it has not been shown to specifically benefit depression. Some elements of the Mediterranean diet, such as omega-3 fatty acids (found in fish), have been found to be beneficial in some clinical trials. Meanwhile, the addition of folate to the diet (with reduction in homocysteine) is associated with decreased symptoms of depression. In countries such as the United States, folate is added to flour, so depression-related folate deficiency is no longer an issue clinically, although not all countries incorporate the addition of folate to food. Thus, clinicians are likely to continue to advocate for adherence to the Mediterranean diet or diets low in fat and high in n-3 PUFAs as part of a general program of health-promoting behaviors, including exercise. It cannot be assumed, however, that supplements like EPA and DHA will confer the same advantages as consumption of fish, whose dietary compilation they are designed to emulate.
The relationship between high saturated fat diets and mental disorders is more complex. It appears that intake of fat may have an acute effect on mood, leading to symptoms of anxiety and depression. In addition, resolution of depression was associated with a reduction in fat intake in some studies, although it is not clear if the reduction in fat led to resolution of depression, or whether resolution of depression led to improved eating habits. Finally, a healthy diet with reduction in obesity will likely have beneficial effects on mental health through improved feelings of wellness and self-esteem, in addition to the known association between obesity and depression. Observational studies of the effects of diet for weight loss and dietary interventions on depression and anxiety have had mixed results, and it is not clear if the science supports clear recommendations for dietary interventions, apart from the does no harm approach. Studies with the greatest effect were those where diet was paired with exercise training, which is significant since studies showed benefits of aerobic exercise equivalent to antidepressants for the treatment of clinical depression [232]. The strongest evidence for a role of diet intervention for depression was in the area of PUFA supplements, specifically higher doses of EPA, for patients with the clinical diagnosis of depression. Since there are essentially no side effects, its use as an adjunct to antidepressants should certainly be considered as part of a treatment armamentarium, although not a substitute for current treatments.
Future studies need to assess the relationship between diet and mental disorders. Future studies should emphasize a multi-disciplinary and integrated approach, the use of epidemiological research methods involving studies in the general population of lifestyles beneficial for health, application of rigorous clinical trial methodology, and promotion of healthy behaviors. Studies of interventions in large communities, including schools, are needed, as well the study of the relationship between diet and health in an international context. Finally, further research in the area of the gut biota, neurotransmitters and neuropeptides, and biological systems in the brain and gut will likely contribute to greater knowledge that can advance treatment for stress-related psychiatric disorders, as well as obesity and MetS.
