Coprophagy,the technical way of saying a dog’s (or other animal’s) tendency to eat their own or other animal’s poop, is possibly more common than you may think, and certainly an issue we are told about here at My Pet Nutritionist. Throwback to the 1940’s and 1960’s and studies on rabbits and rats respectively suggested that it occurred due to vitamin synthesis and the frequency depended largely on nutritional requirements during growth or aging. So, much like Chinese whispers, we have come to the understanding that our dog is eating their poop because they are deficient in something. Findings here. You could stop reading there and have an answer to your question, but you would be wrong. Firstly, your dog isn’t a rat or a rabbit. There’s a little more to this less than desirable habit, so let’s delve a little deeper. What is coprophagy? Coprophagy is common in rats, rabbits, guinea pigs and chinchillas. Rabbits even excrete two types of faeces; hard and soft. Soft faeces are re-ingested but hard faeces are not. If rats are prevented from the act, then they require dietary supplementation of thiamin, biotin, pantothenic acid, folic acid, Vitamin B12 and Vitamin K. Findings here. Based on this information, if you were to notice a dog commonly eating their own poop you would consider that they too did it for nutritional reasons. But it all comes down to the digestive system. In rodents and rabbits, bacterial synthesis of nutrients occurs in the lower gastrointestinal tract. Here, little absorption occurs. By eating their own faeces, it gives them another shot at absorbing the nutrients, for want of a better description. So why do dogs eat their own poop? Well, it has its own name, so it’s nothing new. Canine conspecific coprophagy is regularly mentioned to vets and use alike, and is a regular search term on the world wide web. Some argue that it is a sign of an underlying medical issue,for example: 1) Enzyme deficiency As we know, a key part of the digestive process is enzymatic breakdown. Without key enzymes, food will pass through undigested. There is a school of thought which suggests the dog will eat their own faeces, to give themselves another chance at digesting the food and utilising the nutrients; exactly like the rodents did. 2) Increased appetite There are certain conditions which increase appetite, like diabetes and thyroid issues and so in an attempt to meet their ravenous needs, a dog will eat anything in sight! On the same side of this coin – there are others that argue a dog will eat his own faeces if he is being underfed. That said, the number of obese dogs is increasing year on year, so, before you alter his feeding amounts, check out our blogs: Here and Here. Others argue that it’s not necessarily a health issue, but more a psychological issue. Some have noted that it can occur in bored dogs; whether the dogs are simply amusing themselves, or in fact it’s attention seeking behaviour. For example, many owners don’t like dogs eating poop, so when they spot it, they give the dog attention;despite it being a negative interaction. Think of it like the child who misbehaves as soon as the parent takes that important phone call. However, in order to get a handle on the true reason, a study was conducted that looked at the diet of coprophagic dogs, it looked at house-training, their eating habits and what behaviour modifications had successfully been used in managing it. Findings here. This study found that the diet of the dog had no significant impact,therefore suggesting no nutritional basis for the behaviour and coprophagic dogs were just as easily house-trained as non-coprophagic dogs; so, they still maintained a typical aversion to faeces like most dogs. Interestingly, those dogs who ate their own poop, were more readily described as greedy eaters. Sadly, the success rate of behaviour modification to stop the dog eating their own poop was close to zero. Let’s see if their like of other animal’s poop sheds anymore light on the reasoning behind this particular behaviour. Why do dogs eat cat poop? The most likely explanation is that whatever hasn’t been absorbed by the cat during their digestion, attracts the dog to eat the poop. In some commercial cat foods, compounds are added to make the food palatable; these aren’t always absorbed by the cat, so they just come out the other end. Why do dogs eat another dog’s poop? There’s little evidence to suggest a nutritional basis for eating another dog’s poop. The factors relating to a dog eating faeces include: Greedy eating Breed group (hounds and terriers are more likely to do so) Multiple dogs in the house Eating dirt Eating cat stools It doesn’t appear to make a difference whether they are eating their own, or another dog’s poop – if they are going to eat poop, they’re going to eat poop. Why do dogs eat wild animal poop? When you’re out on your walks with your poop eater, he’s probably found rabbit or horse poop. Why are they drawn to it? The explanation could lie in their plant-eating habits! With horses and rabbits being herbivores, are dogs seeking the plant content of their poop? Again, grass-eating is not linked to nutritional deficiency or illness. Some owners perceive it as a way for dogs to make themselves sick. But dogs fed commercial, table scrap or raw diets were no more prone to grass or plant eating than the others. The answer to this question takes us back to their ancient beginnings. Plant-eating seemed to play a role in controlling internal parasites. Plant material passes through the intestinal tract, wrapping around worms and thereby clearing them out. Findings here. The parasites would then be found in the faeces, which leads us to another reason why a dog would eat poop – to keep their den clear of parasites. Some domestic dogs take themselves off to the furthest point
Whilst we often reference lip licking in anticipation food, there are a number of reasons why dogs especially, may demonstrate this behaviour. Some may even surprise you. So, let’s take a look at some of the more common reasons for lip smacking, or licking, that we see here at My Pet Nutritionist. 1) Anticipation of Food! We can head back to Pavlov and his dogs to put this behaviour into context. Most of us are familiar with the concept of conditioning that Pavlov introduced – he paired a bell with food, and eventually, the dogs would salivate in anticipation of the food, just by hearing the bell. This increase in salivation will encourage lip licking to help manage the extra fluid in the mouth! But what is also interesting is that food also stimulates the reward system in the brain – and the physical response to this type of reward is often saliva – again, the lip licking is a mechanism to manage the extra fluid in the mouth. 2) Lip Licking in response to stress! Not surprisingly, stress can result in hypo (too little) and hyper (too much) salivation! Either way, lip licking is often the result. On the one side, activation of the sympathetic nervous system (fight or flight), redirects resources and in doing so, digestive functions are sacrificed. As saliva is an important part of the digestive process, production is therefore reduced. The resulting dry mouth can encourage lip licking behaviour. Licking is also a maternal behaviour – they would clean and groom their offspring, soothing them during the action. Many dogs demonstrate licking behaviour because it elicits positive responses. It is well demonstrated that those born to Mothers who engaged in grooming/licking behaviour, are more resilient to stress, and develop more appropriate coping mechanisms. Findings here That said, increased salivation can be implicated in certain health issues that are exacerbated by stress – here salivation may be a side effect of an underlying issue, like acid reflux. 3) Acid Reflux Acid reflux is where stomach acid ends up somewhere it shouldn’t. As we know, the body is pretty nifty and has a few tricks up it’s sleeve to deal with rogue compounds. In response to the irritant in the oesophagus (stomach acid), salivary glands can over produce in an attempt to neutralise it. Ironically, acid reflux can be a result of reduced salivary production in the first place. There are a number of causes of acid reflux, poor lower sphincter functioning, abnormal oesophageal clearance, altered mucosal resistance and delayed gastric emptying (which is why it can be implicated alongside stress). If you would like more information about tackling acid reflux, then check out our blog here. 4) To smell better! Dogs use their tongues to enhance their sense of smell. When they lick a surface their transfer molecules via their tongue to olfactory receptors and then to the vomero nasal organ. When a dog keeps their nose wet, they are lowering the surface tension of the scent molecules so they can be translated better! Dogs are incredible at detecting minute traces in their environment – this also applies to information from us humans. We must consider whether our dog is attempting to gain more information about those around him when he is licking his lips. 5) Gastrointestinal Disorder Lip licking is often paired with nausea,along with excess salivation, lack of appetite, increased swallowing and lethargy. For this reason, it is often considered that lip licking is more likely associated with some gastrointestinal disorder or discomfort. One particular study sought to investigate this. Dogs demonstrating excessive licking behaviour were studied. In 14 of 19 licking dogs, gastrointestinal abnormalities were noted. They included: Delayed gastric emptying Irritable bowel syndrome/disease Food intolerances or allergies Pancreatitis Gastric foreign body Giardia Researchers concluded that full gastric health should be considered in any dog presenting with excessive licking behaviour. Findings here If you would like a head start on supporting your dog’s digestive health, then check out our blogs here: The Dog’s Digestive System 7 Steps to Optimal Gut Health for Your Pet Natural Guide for Pets IBD Pancreatitis and a Natural Nutrition Regime 6) Disorders of the Mout Gum disease is an inflammatory condition,symptoms include bad breath, drooling along with mouth and tongue inflammation. Sadly, bacteria can be translocated from the mouth into the rest of the body, often causing secondary infections and issues. For more information on dental care for your dog check out our blog here. But disorders of the mouth aren’t limited to periodontal disease. They can also include lip disorders found in those breeds with dropping upper lips and lower lip folds (like spaniels,bulldogs and St. Bernards). The lips accumulate moisture, becoming the perfect breeding ground for harmful bacteria. The lip folds can become fowl-smelling,inflamed, uncomfortable and swollen, resulting in your dog licking them to try to soothe them. Keeping these folds is therefore essential to your dog’s health! As is supporting their skin and oral microbiome. Please check out blog on puppy microbiome here. Your dog can also develop lip wounds – from a rogue branch or grass seed that has gotten wedged. If you are concerned about your dog’s lip licking behaviour – checking in their mouth is a good place to start. These are the more common reasons why your dog may be licking their lips, but they are not the only ones. Your dog may lip his lips for any one of the following reasons: Medication side effect Infectious disease Car sickness Reluctance to swallow (irritation/blockage) Inflamed tonsils Structural defects in the mouth Metabolic disorder (liver or kidney issues), Natural Guide To Liver Disease and Natural Nutrition Guide to Kidney Disease. Abscess. Disorder/blockage of the salivary glands Pain Whilst we can’t change the structure of your dog’s mouth, we have a wealth of experience tackling gastrointestinal disorders in the canine. If you are concerned about excessive lip licking in your dog and are wondering where to start, check out our services to see
Did you know that body wasting is found in 65-90% of patients with advanced liver disease? These patients often develop micronutrient deficiencies which ultimately results in malnutrition. Being a more common disease than we’d like to see here at My Pet Nutritionist, it is clear that there are nutritional implications in any treatment plan. For that reason, we thought we’d explore liver disease in a little more detail, with specific reference to food choices. What is Liver Disease? Liver disease can present in many different ways – it can range from chronic hepatitis, acute liver failure, portosystemic shunts to hepatic encephalopathy. For more information on these specific manifestations, check out our blog here. Here you will also find any signs and symptoms to look out for. But before we get into what happens when it goes wrong, let’s look at what a healthy liver does. The major functions of the liver include: Bile production: Bile helps the small intestine breakdown and absorb fats, cholesterol, and those fat soluble vitamins. Bile consists of bile salts, cholesterol, bilirubin, electrolytes, and water. Absorbing and metabolising bilirubin: Bilirubin is formed by the breakdown of haemoglobin. The iron released from haemoglobin is stored in the liver or bone marrow and used to make the next generation of blood cells. Supporting blood clots: Vitamin K is necessary for the creation of coagulants that help clot the blood. Bile is essential for vitamin K absorption and is created in the liver. If the liver does not produce enough bile, clotting factors cannot be produced. Fat metabolisation: Bile breaks down fats which makes them easier to digest. Metabolising carbohydrates: Carbohydrates are stored in the liver, where they are broken down into glucose and siphoned into the bloodstream to maintain normal glucose levels. They are stored as glycogen and released whenever energy is needed. Vitamin and mineral storage: The liver stores vitamins A, D, E, K, and B12. The liver stores iron from haemoglobin in the form of ferritin, ready to make new red blood cells.The liver also stores and releases copper (which is why copper toxicity in dogs is associated with liver failure). Filters the blood: The liver filters and removes compounds from the body, including hormones and compounds from outside the body, like medications. For more information on detox, check out our blog here. Immunological function: The liver is part of the mononuclear phagocyte system. It contains high numbers of Kupffer cells that are involved in immune activity. These cells destroy any disease-causing agents that might enter the liver through the gut. Production of albumin: Albumin is a protein found in the blood. It transports fatty acids and steroid hormones to help maintain pressure and prevent the leaking of blood vessels. It is the higher circulating albumin found in dogs that suggests they possess an increased fat oxidation capacity, in comparison to humans. Synthesis of angiotensinogen: This hormone raises blood pressure by narrowing the blood vessels when alerted by production of an enzyme called renin in the kidneys. But perhaps the most interesting function of the liver, is its ability to regenerate. In mice, if two thirds of their liver is removed, the remaining tissue can regrow to its original size within 5-7 days! In humans, this process takes slightly longer, but it can still occur. In dogs, the mechanism is thought to occur similarly to that in the mouse., but maximum response is seen after three days, as opposed to 24-hour peak in rat regeneration. Findings here Liver Guard This regeneration is helped by a number of compounds, including growth factors and cytokines like: hepatocyte growth factor insulin transforming growth factor-alpha epidermal growth factor interleukin-6 norepinephrine Micronutrients to Support Liver Health Almost all chronic liver diseases are under the background of elevated oxidative stress. Great sources ofessential antioxidants are foods rich in vitamin C, vitamin E, and trace element selenium. Plant foods also contain compounds that have antioxidant activity, such as ascorbic acid, beta-carotene, coenzyme Q10, curcumin, ellagic acid, epigallocatechin gallate, lipoic acid,lycopene, N-acetyl cysteine, quercetin, and resveratrol. Blueberries This versatile berry contains anthocyanins, an antioxidant, protecting the liver from oxidative stress. Studies have found that in the livers of rats, such protective compounds found in fruits like blueberries slowed the development of scar tissue, and may be useful in the prevention of hepatic fibrosis. CruciferousVegetables (Brussel sprouts, broccoli) Not only does this family of vegetables provide a wide range of nutrients and health benefits, they also have the added ability of increasing the liver’s natural detoxification enzymes and improving overall liver function by decreasing oxidative stress. Findings here Nuts Nuts, which are high in healthy fats and Vitamin E (a powerful antioxidant) as well as other phytochemicals, have shown potential for treating non-alcoholic fatty liver disease by reducing inflammation and fat accumulation in the liver. Fatty fish (mackerel, tuna, salmon, trout) Consuming fatty fish that are high in omega-3 fatty acids regularly can modulate inflammation and enzyme levels. Findings here A review of plant-based foods for liver health indicated the following as beneficial: broccoli carrots collard greens kale sweet potato cabbage banana papaya pomegranate watermelon Findings here Patients with liver disease are advised to avoid nightshade plants like tomatoes and eggplant as they can become hepatotoxic. Macronutrients to Support Liver Health The liver plays a crucial role in the metabolism of proteins along with carbohydrates and fats. It carries out four main functions in protein metabolism. The first is the formation of blood proteins. These blood proteins include clotting factors, carrier and transport proteins, hormones, apolipoproteins, and other proteins involved in homeostasis and the maintenance of pressure, such as albumin. The liver is also involved in amino acid interconversion. Amino acids are divided into two groups, essentials—those that the body is unable to produce,which must be obtained from the diet and non-essentials, those that the body can synthesise. The liver is able to alter the structure of amino acids and transfer amino radicals to a keto acid to produce the amino acids needed for the body. This process is critical in many body functions, especially gluconeogenesis. The third function is amino acid deamination, or breakdown, the by-products
You are what you eat! This is a phrase that has dominated the media for decades. On a biochemical level it’s true – each cell in the body has a function, to carry out that function, it needs nutrients, co-factors and energy. Whilst some nutrients and cofactors can be synthesised within the body – in one way shape of form, what cells need must come from somewhere, and that somewhere is the diet. This also applies to the cells that tell us, and our dogs how to behave, or more interestingly, influences how us or them feel. So, can food affect behaviour? It sure can! But the full answer needs a little more explanation, so grab a coffee and join us as we take a look at the link between food and mood, and specifically which compounds or foods may play a role. What is Mood? Mood is the way us or our dogs are feeling at a particular time and they can change – depending on internal and external factors. Although they can change – moods still have physiological symptoms – for example, during anger, heart rate increases and in humans, a noticeable red flush to the face. When calm, heart rate reduces. Being focussed or distracted is also a mood and this is largely affected by biochemical processes too. In this case, the right balance of dopamine. Dopamine is a neurotransmitter, and these chemical messengers are in fact a key element in how food can influence behaviour. Neurotransmitters are like the nervous system’s carrier pigeons. The main neurotransmitters that do that work are acetylcholine, dopamine, gamma-aminobutyric acid (GABA), glutamate, histamine, norepinephrine and serotonin. Neurotransmitters can be excitatory, or inhibitory. They either make something do something or stop something doing something. Like an accelerator and a brake pedal. All of these neurotransmitters must be made from something. We can think of it like a recipe for behaviour – we have main ingredients, but we also need some seasoning (co-factors)! So, let’s take a look at the recipe book for some of the heavy lifting neurotransmitters. Acetylcholine Acetylcholine stimulates muscle contraction, both skeletal and smooth. It is also involved in attention, memory, and learning. Acetylcholine is needed in high amounts during waking hours, but in low levels during restorative sleep. In most cases acetylcholine is excitatory. What is of interest is that acetylcholine is released by nerve cells during times of mild stress (or concentrating on learning something new), so during these times, demand is increased. Acetylcholine is synthesised from choline and it is carried out in the liver. Sources of choline include egg yolks, liver, kidney and seeds. Dopamine Dopamine can be both inhibitory and excitatory depending on the receptors it acts upon. It contributes to the control of voluntary movement and influences learning, attention, and emotion. It is largely associated with reward mechanisms in the brain and plays a part in pleasure seeking. Dopamine gets particular interest in incarcerated humans, but also in aggression in dogs. Aggressive dogs have been found to have significantly different alleles for dopamine receptors than their non-aggressive counterparts; short form alleles demonstrate greater impulsivity. Whilst it is easy to suggest that aggression and impulsivity is in the genes, there are processes that can regulate gene expression. DNA methylation is one such epigenetic mechanism. If you would like to know more about this then check out our blog here. Findings here Dopamine is synthesised from phenylalanine and tyrosine which are both amino acids. Sources of phenylalanine include dairy, eggs, nuts, chicken, beef, pork and fish. Sources of tyrosine include chicken, turkey, fish, bananas, yoghurt, pumpkin seeds and sesame seeds. Dopamine is broken down by a couple of enzymes, and there can be genetic variants which affect how quickly it occurs –for some, dopamine may hang around a little too long, for some it may disappear incredibly quickly. Increased breakdown can lead to attention deficit behaviour and often fatigue like behaviour. On the other side of the scale, decreased breakdown is sometimes noted in aggressive behaviour. Altered protein intake can sometimes help to balance this out. GABA GABA is the primarily inhibitory neurotransmitter in the brain, this stops the firing of neurons and we call it the breaks on the brain. By inhibiting neural activity, GABA facilitates sleep, reduces mental and physical stress, lowers anxiety, and creates a calmness of mood. Its relationship with glutamate is key to overall balance. GABA also modulates intestinal motility,gastric emptying, and gastric acid secretion. Findings here GABA’s recipe includes an amino acid too, glutamine. Sources of glutamine include beef, chicken, dairy, fish, eggs, cabbage, spinach, carrots, kale, and papaya. Serotonin Serotonin has a wide-ranging role in the body including regulation of energy balance, food intake, and GI and endocrine function. But its behavioural processes include mood, perception, reward, anger, aggression, appetite, memory and attention. In cases of canine aggression, serotonin levels are found to be significantly lower than their non-aggressive counterparts. Serotonin is synthesised from tryptophan, but you might already know this! However, in times of stress, tryptophan gets stolen. We’re not lying. It’s called the “tryptophan steal”. Tryptophan also feeds another pathway in the body, known as the kynurenine pathway which is a necessary pathway, but in times of stress or inflammation this pathway steps up a notch and siphons the little tryptophan we did have! Foods to boost serotonin: Banana Pineapple Pomegranate Strawberry Spinach Nettle Kiwi Lettuce Tuna Turkey Chicken Oats Nuts and Seeds Glutamate Glutamate has excitatory effects on nerve cells, and it can actually excite cells to their death. Both too much and too little glutamate are harmful. The oversupply of it can lead to seizures, and environmental stress can significantly enhance glutamatergic release. Findings here But like everything in the body, we’re looking for goldilocks – just enough! Glutamate occurs naturally in protein-containing foods like diary, mushrooms, meat, fish and some vegetables. Histamine Histamine is a transmitter in the nervous system and a signalling molecule in the gut, skin, and immune system. It is
Is it true that DNA is our destiny? This concept is much like Schrodinger’s cat – a paradox. With Schrodinger, his cat was both alive and dead until his box was opened. With our DNA, we can blame our Grandma for something that has gone wrong, but equally how we choose to live our lives can also affect whether or not we have something to blame Grandma for. Are you lost yet? So were we. But here at My Pet Nutritionist, we like to give you, as pet owners tools to support your pet’s health, so we’ll give you the 411 on DNA and how we can use nutrition to lessen how much we blame Grandma for (or Grandad, could be him too!) Pretty nifty, don’t you think? This is what we call nutrigenomics. Let’s start off with some key definitions: Genomics: This is the study of all genes and gene products. It explores how they interact and influence biological pathways, networks and physiology. Nutrigenomics are therefore a subset of genomics with focus on the genes that relate and respond to nutrition and lifestyle interventions. As it’s relevant, epigenetics is the study of how the environment and other factors can change the way that genes are expressed. Epigenic markers are chemical compounds that are added to genes to regulate their activity. Whilst these modifications do not change theDNA sequence itself, epigenetics affects how cells read genes and whether the cells should produce relevant proteins. The point to note is that DNA doesn’t change – gene expression does. This is where the idea of turning genes on and off comes from – epigenetic markers can turn genes on, and off. Gene Writers Much like I’m writing this blog now, we can think of our DNA having workers at a word document. The fact that I had a nutrient dense breakfast and have a cup of tea next to me, with the birds singing by my window, places me in good working conditions. The blog should therefore make sense – be well-formatted and do the job it is meant to do (share information). If I had not slept for days, gorged on ultra-processed food, and been bombarded with stressors, the blog may not make as much sense, it may even have a few typos, and not in fact do you the job it was meant to (you have no clue what I was writing about). Our gene workers are similar. If they have supportive working conditions,they do what they are supposed to, they send the correct information out; cells know what they are supposed to do, and they even know when they’re not supposed to be doing anything. If they have poor working conditions, they send out half finished messages (or coding), which may contain typos; cells don’t really know what they are supposed to be doing and start to go a little rogue. The genome is malleable – our genes are like a word document – it is a living document. They also eavesdrop on every choice we make, or those we make for our pets. Dirty Genes and those that just act Dirty The reason we think DNA is destiny, is because its partly true. When us, or our pets are born, we have our very own DNA. Within that, there may be these alterations, or variants known as single nucleotide polymorphism (or SNPs, we call them snips). These SNPs can cause problems – they are like the inbuilt typos on your word document. Like the Microsoft paperclip assistant that would always pop up no matter how many times you tried to get rid of him! So, both us and our dogs can be born with dirty genes that send unclear messages to our cells. But, lifestyle, and nutrition, can also make the genes dirty. Luckily, we live in an age of washing machines, so we’ve got some great ways to clean them up again! One of the ways in which our DNA expression can be altered is through methylation. This is the addition of a methyl group – demethylation is the removal of a methylation group. Methylation is a key chemical process for every cell and cellular activity, constantly and dynamically regulating our daily function. It supports growth and repair, immune function, synthesis of neurotransmitters and phospholipids, and plays an important role in detoxification. If you’d like to know more about detoxification then check out our blog here. But what is also nifty is this positioning of the methyl groups can be passed down from generation to generation – which ultimately affects the health of future generations. Take note breeders! Poor DNA methylation has been increasingly associated with many diseases, from cancer to autoimmunity. And of course, this process requires a number of co-factors. Where do these co-factors come from? The Diet. Nutrients crucial in DNA Methylation: Folate: spinach, broccoli, romaine lettuce, daikon radish, liver. Vitamin B12: liver, sardines, salmon, lamb, beef, dairy, all meat,eggs. Vitamin B6: spinach, cauliflower, all meat, liver, sweet potato, salmon, leafy greens, daikon radish, liver. Vitamin B2: spinach, beetroot, mushrooms, eggs, broccoli, kale,peppers, daikon radish, liver. Zinc: beef, spinach, mushrooms, lamb, pumpkin seeds, turkey,seafood. Magnesium: leafy greens, pumpkin seeds, spinach, sunflower seeds,daikon radish. Choline: egg, collard greens, brussels sprouts, spinach, chicken, turkey, salmon, sardines, beef. Betaine: spinach, sweet potato, turkey, veal, beef, liver. Methionine: nuts, beef, lamb, turkey, fish, shellfish, eggs. Not surprisingly, ultra-refined foods place a strain on methylation, which is why we would always advocate a fresh, wholefood diet for your pet. So if you want efficient methylation processes – ensuring a sufficient supply of these co-factors is essential. There are also certain food compounds which ultimately affect gene expression through their influence on DNA methylation. This is where the concept of nutrigenomics comes in. Polyphenols Catechins have been seen to modulate gene expression. They are polyphenolic compounds found in plants. Sources include apples, blackberries,pears, green tea (opt for decaf if you’re feeding it to your dog). They also exhibit antioxidants
In 1988 a hospital launched a “healthy eating day” in its staff canteen at lunchtime. One dish contained red kidney beans, and 31 portions were served. At 3pm one of the customers, a surgical registrar, vomited in theatre. Over the next four hours10 more customers suffered profuse vomiting, some with diarrhoea. All had recovered by next day. No pathogens were isolated from the food, but the beans contained an abnormally high concentration of the lectin phyto haemagglutinin. What on earth are these we hear you wonder? Well, lectins are often described as an anti-nutrient and as they are found in potatoes, beans, lentils, peas, soybeans, nightshade vegetables and grains, we thought we’d give you the 411 on them. Lectins are carbohydrate binding proteins present in most plants, especially seeds and tubers like cereals, potatoes, and beans. Their original purpose was protection. They would produce an inflammatory response in the animal that ate them – so they wouldn’t eat them again. Humans and Dogs are largely unable to digest them, but friendly bacteria in the gut can lend a hand. Until recently their main use was as histology and blood transfusion reagents, but in the past few decades we have realised that many lectins are (a) toxic, inflammatory, or both; (b) resistant to cooking and digestive enzymes; and (c) present in much of our food Well, it’s not sounding good is it! The really disturbing finding came with the discovery in 1989 that some food lectins get past the gut wall and deposit themselves in distant organs. At high dietary levels, it is thought that lectins cause damage to the structure of the brush borders of the small intestine. In lectin fed rodents, the mucosal membrane in the small intestine was stripped, compromising the gut integrity. This compromise has also been linked to abnormal bacterial proliferation. Findings here As we know, the gut wall does exactly that – keeps things in and keeps things out! It requires tight junction integrity to ensure rogue particles of food don’t get where they shouldn’t. Whenever and however this integrity is compromised, inflammation ensues! The other issue here is that lectins are also seen to inhibit the repair of resident gut epithelial cells. Sadly, not only do rogue particles get where they shouldn’t, but so do the lectins and because of their binding properties, lectins stimulate antigens on cells that do not normally display them like pancreatic islet and thyroid cells – what this means is the body will attack cells it normally wouldn’t because of the confusion. This is why lectins are sometimes implicated in autoimmune disorders, including cases of rheumatoid arthritis. Lectins and Rheumatoid Arthritis A normal IgG (type of antibody) molecule possesses carbohydrate side chains, which end with the molecule galactose. In rheumatoid arthritis much of the galactose is missing, so the next molecule along—N-acetyl glucosamine—is exposed instead. Wheat lectin has an affinity for this molecule, and so binds (when it normally wouldn’t with the terminal molecule inits normal place). This is why glucosamine has found it’s way as an anti arthritic supplement – wheat lectin can be blocked by N-acetyl-glucosamine. Lectins and Urinary Tract Infections In a similar premise, D-mannose is a sugar with a similar activity to N-acetyl-glucosamine. This too binds to lectins found on some microorganisms. Some bacteria responsible for urinary tract infections contain lectins specific for the sugar mannose and use these lectins to bind tightly to mannose -rich tissue in the bladder walls – therefore initiating infection. D-mannose supplementation provides a decoy for these bacteria. Lectins and Gluten There is also the idea that gluten can act as a lectin with toxic properties for intestinal cells. Together with the gut-associated lymphoid tissue and the neuroendocrine network, the intestinal epithelial barrier plays a role in the tolerance and immunity to non-self-antigens. Zonulin is a protein that helps regulate permeability in the gut by opening and closing tight junctions. Zonulin has been shown to be upregulated in many autoimmune diseases and it appears that gluten may be a strong trigger of zonulin. Lectins and Histamine Lectins also cause discharge of histamine from gastric mast cells which stimulates acid secretion. We need acid secretion to aid digestion, but it’s like the story of Goldilocks again – we need just enough, not too much (or too little). Not only does histamine stimulate acid secretion, but it has also its own little purpose in the body, chiefly the immune response. So, not only do we have rogue particles escaping due to poor gut integrity (thanks to lectins), but we also have increased histamine production, when then increases the likelihood of cross-reactivity. In short, tricking the body into thinking it needs to react to something it most likely doesn’t. Can you see why lectins are often dubbed the great mimics? They confuse the body into doing all sorts of things. They also appear to mimic insulin. Now, insulin is needed in the body, it helps get glucose to where it needs to be, but do we really need things mimicking it? Not when “Low concentrations of wheat germagglutinin (plant lectin) enhance the specific binding of insulin to receptors of fat cells and liver membranes.” Findings here In this case, imitation is not the sincerest form of flattery. But there are other reasons why lectins are deemed anti-nutrients. Animal and cell studies have found that active lectins can interfere with the absorption of minerals, especially calcium, iron, phosphorus, and zinc. Legumes and cereals often contain these minerals, so the presence of lectins may prevent the absorption and use of these minerals in the body. As we have already explored, lectins can also bind to cells lining the digestive tract which may also disrupt the breakdown and absorption of nutrients and affect the growth and action of intestinal flora. However, on the other side of the scale, lectin containing foods are sometimes associated with lower rates of cardiovascular disease and diabetes, because they are rich in fibre. So, what do we do? Lectins are most potent in their raw
An elimination diet – the wand of all wands. Or at least we would like to think so. Here at My Pet Nutritionist, we regularly utilise elimination diets in our healing plans. But there is often some confusion over their purpose and how best to use them. So, we thought we’d cover, what they are, what they hope to do, and what they can’t do. What is an elimination diet? An elimination diet, also known as exclusion diet, is a diagnostic procedure used to identify foods that an individual/animal cannot consume without adverse effects. Adverse effects may be due to food allergy (IGE), food intolerance (IGG), other physiological mechanisms, or a combination of all of the above. The point to note here is that it is a diagnostic tool – not a long-term lifestyle and in some cases, a means to give the immune system a welcomed break. People often look at certain foods being the culprit or the saviour. But what’s really happening is the bodies inability to deal with certain antigens effectively. As we know, the immune system functions like a radar – always on the lookout for potentially harmful compounds. But, through regular activation it can become hypersensitive and seemingly forget that it does have a tolerance capacity too. Immune Tolerance In the body, there are two types of immune tolerance, one is self-tolerance, and this prevents the development of autoimmune disease. The body accepts its own cells and doesn’t try to kill them (so kind!). But there is also this idea of induced tolerance. Induced Tolerance Induced tolerance occurs when the immune system actively avoids responding to an external antigen. This tolerance is induced by previous encounters with that antigen. An example of induced tolerance is a deliberate manipulation of the immune system to avoid the rejection of transplanted organs or to provide protection from allergic reactions. But induced immunity needs a fully functioning immune system to make the right calls at the right time – this is the basic premise of why we want to carry out an elimination diet. To see what foods might elicit a reaction. Through the removal of antigenic compounds (the foods potentially wreaking havoc), you remove the adverse responses pulling on resources and you can then spend time supporting the various systems in the body, including the immune system, to get your ducks in a row. Why would you do an elimination diet? An elimination diet is often the first port of call for dogs suffering with allergies, intolerances, inflammatory conditions and also behavioural issues. This last point often raises a few eyebrows –but as we know, immune responses are intricately linked with the brain and subsequently behaviour. We not only have sickness behaviour, which makes us hunker down and prevent the spread of virus (evolutionary purpose for survival), but pain simply makes us, and our dogs, miserable. In cases of irritable bowel syndrome, there is a noted visceral hypersensitivity too, which in a nutshell means an even higher sensitivity to pain (and sadly an increased propensity to be miserable). The take home? Allergies, intolerances and inflammatory conditions are all an immune response. So, the point is to lighten the load on the immune system. But we can’t forget there are differences between allergies and intolerances. A food allergy or other allergic response is caused by an IgE antibody reacting towards that allergen. IgE binds to mast cells to promote histamine release. This is an immediate response and in some to certain food allergens can be fatal (anaphylaxis). Hives or instant rashes and swelling can be seen. IgA is an antibody that lives in mucous membranes, inside nasal cavities, and lungs. It helps to protect the respiratory tract as a first line of defence. IgM is the first immunoglobulin that is encountered in an infection, or vaccines for the first time. IgG is the work horse antibody; it is the soldier, the memory antibody. This is what gets drafted when your dog is exposed to something they have already figured out a response to. When you have a food intolerance, we tend to discuss it in terms of IgG. Symptoms usually begin within a few hours of eating the food that you are intolerant to. Yet, symptoms can be delayed by up to 48 hours and last for hours or even days, making the offending food especially difficult to pinpoint. IgG’s are mostly raised from the barrier mucosa in the digestive system. After a meal, there are both antibodies and complexes of food antigens bound to specific IgG’s. These complexes are quickly cleared by the reticuloendothelial system. Clinical observations suggest that due to gut inflammation and permeability (leaky gut), the digestive system is unable to digest the proteins effectively which subsequently raises IgG response to certain foods. We know that chronic intestinal inflammations and permeability are related to and possibly responsible for food IgG sensitivity. 90% of food reactivity comes from IgG’s. Just to confirm, intolerances can be changeable but allergies tend to be for life and only account for around 10% of food reactivity. IgG’s come in different categories but to keep it simple, they are generally defined as cyclic or fixed. A common IgG reaction is cyclic and can take around 3 months to disappear/change. A fixed Intolerance tends to linger for longer and can take around 6 months to disappear/change. So how do we move forward? We prime and reset the digestive system, and this includes starting with an elimination diet but also gut healing and immune balancing protocols. We follow the 4 R’s. – Remove – carry out an elimination diet. Remove offending foods, one at a time and note changes in symptoms. Quite often, even offending foods can be reintroduced at a later stage. – Repair – support immunity and gut healing with ingredients like slippery elm, de-glycerised liquorice, glutamine, andN-acetyl-glucosamine. It is also important to consider how existing medications are affecting gut healing for example, steroid use impairs intestinal absorption which is linked to several gastrointestinal dysfunctions. But, because of their anti-inflammatory and immunosuppressive activities,
Would you believe that around 70% of the consultations we carry out here at My Pet Nutritionist are surrounding allergies? The reasons for this are largely multi-factorial and bigger than the scope of one blog article, but as in the words of someone much smarter than us – you’ve got to start somewhere – so we thought we’d explore histamine in a little more detail. What it is, what it does, if indeed it is found in foods and whether there is anything, we can do to reduce the load. So, let’s get cracking. What is histamine? Histamine is a transmitter in the nervous system and a signalling molecule in the gut, skin, and immune system. It is synthesised from the amino acid histidine which is in fact an essential amino acid for humans and dogs. Before we knew better (and in some labs we still don’t), animal studies established that histidine deplete diets result in dog death! Findings here Histamine is primarily associated with the functioning of the immune system. During an immune reaction, histamine is released and contributes to the physical changes necessary for the immune system to fight the pathogen, including the increase in blood pressure, temperature, swelling, and constriction in the lungs. Like all things in the body, histamine needs receptors for it to do its job and there are especially high concentrations of histamine receptors found in the lungs, skin, blood vessels, and gastrointestinal tract. Histamine is stored in granules in mast cells throughout the body and as we know mast cells mediate inflammatory responses such as hypersensitivity and allergic reactions. The granule protects the histamine; if histamine could float freely it would degrade very quickly. Histamine is released from those granules in response to tissue injury resulting from cold, heat, toxins, and trauma. As noted, there are numerous histamine receptors throughout the body. H1 and H2 receptors are of most interest in the hypersensitivity and allergic response (but there are H3 and H4 too). H1 receptor binding results in a range of actions. Peripheral sensory neurons are acted upon which causes itching and sometimes pain. Intestinal smooth muscle is affected causing constriction, cramps and possibly diarrhoea. H1 receptor binding can result in secretory mucosa causing bronchi and nasal mucus. Lastly the pulmonary smooth muscle can be affected resulting in constriction. There are some tissues that have both H1 and H2 receptor binding sites. This includes the cardiovascular system. Histamine binding here drops blood pressure by widening the blood vessels. It also increases heart rate. There are also dermatological effects resulting in increased permeability. This is often described as the triple response resulting in the reddening of the skin, wheal formation and an irregular “halo” flare, also known as hives. H2 receptor binding sites are more commonly seen in the stomach itself. Histamine can bind to parietal cells stimulating the secretion of gastric acid. This is why antihistamine medication is sometimes implicated in digestive dysfunction due to the lower secretion of gastric acid – which is ironic, when partially digested proteins can then become antigenic. H1 receptors are involved in type 1 hypersensitivity reactions (involves immunoglobulin E – IgE – mediated release of antibodies), H2 are involved in Th1 lymphocyte cytokine production, H3 are involved in blood-brain barrier function and H4 are also expressed on mast cells exacerbating histamine and cytokine generation. The long and the short of it, histamine stimulates inflammation and is a prominent contributor to hyper sensitivities and allergic disease (but it is only one of many mediators of allergic disease). Histamine kick starts the processes to get rid of the offending particle/s – whether this is to sneeze pollen from your nose, or to expel food allergens from the gut, but it also plays a role in wakefulness, appetite, and endocrine homeostasis. So, histamine is in fact necessary to maintain homeostasis (balance in the body). But there can be too much of a good thing. Histamine is released to carry out a function and then it is removed by a few different pathways. The enzymes we are particularly interested in are diamine oxidase (DAO) along with histamine-N-methyltransferase (HNMT). DAO inhibition or disruption can result in disproportionate amounts of histamine in the body which can result in a range of GI symptoms along with cardiovascular, respiratory, and skin complaints. Disruption of HNMT function, on the other hand, tends to affect the nervous system. HNMT inactivates histamine by transferring a methyl group, so methylation is a key process in maintaining HNMT activity. Methylation is a relatively simple process, but it occurs billions of times every second! It underlies the proper function of virtually every body system. It is dependent on certain key nutrients like folate in its active form, methyl folate, B12 and B6. There are a number of factors that can affect methylation, from nutrition to genes, but stress and vaccination is a major drain on it. The stress response is a sequence of processes that relies on methylation, depleting key nutrients as it goes. Therefore, if methylation isn’t efficient, HNMT isn’t efficient, and histamine can become imbalanced affecting behaviour, sleep, appetite, immune function and digestion. A range of factors can increase histamine in the body such as infections, B12/folate deficiency, magnesium deficiency, stress, inflammation, trauma and exercise. Not only that but certain gut bacteria produce histamine. DAO and HNMT can become flooded when there is a high histamine load, subsequently affecting breakdown. Histamine load can be increased by the ingestion of high-histamine foods too, but the release of it can also be promoted in the body, by foods we know as liberators. The following list is of foods to avoid if opting for a low-histamine approach to hypersensitivity, whilst getting to the bottom of things. Fermented foods (kefir, sauerkraut etc, prebiotics) Tripe Vinegars (including ACV) Long-stored nuts Beans and pulses Canned foods Citrus fruits Banana Wheat germ Spinach Canned fish (salmon can contain more histamine than most) There is also discussion around yeast behaving as a histamine generating catalyst, so the general rule
The Universe inside your Puppy Here at My Pet Nutritionist we always focus on microbrial health, so we delve into it’s importance for your puppy to hopefully set them up for life. Microbes have been around for billions of years, humans – less than a million and we all know there is much disagreement over the domestication of our faithful furry friends. Microbes can multiply in minutes, survive and thrive in every habitat on earth, and technically, they’ve killed more people than all wars combined. But, without them, we actually couldn’t survive. Microbes are like a bad version of Ed Sheeran, you need me, I don’t need you. The body is in fact like a mini ecosystem. It has many different microbial communities throughout the body. They live inside; in the lungs, nose, urinary tract, and digestive tract, but they also live on; they are all over the skin! Because you sadly have jobs that need to get done today, we’re just going to do a whistle stop tour of the three main microbial communities and how we can support them in the puppy. First up, the skin microbiota. Not surprisingly, the skin microbiota plays a role in skin conditions like atopic dermatitis and even some skin cancers. Check out our blog on atopic dermatitis in pets here. In the dog, there are different communities found in different areas of the skin; there are also clear differences in diversity between healthy and allergic dogs. The skin provides one of the first lines of defence in the immune system, but in two ways. Not only does it have its physical structure to keep things in, and things out, but the community of microbes on the skin also protect against potentially harmful pathogens. The good guys can engulf the bad guys before they gain entry into the body, but they can also compete for nutrients and resources, to prevent the bad guys from thriving. In utero, foetal skin is thought to be sterile. But colonisation of microbes occurs during and immediately after birth. As the newborn puppy moves through the birth canal, he is exposed to a variety of bacteria from Mum. Once puppy is born and grooming begins, Mum passes even more over to her offspring. Mum health is therefore imperative – not only for the diversity she possesses but also her emotional health. Stressed Mum’s are less likely to engage in grooming behaviour, so if she isn’t grooming her offspring, she’s not passing her microbes to them. The environment greatly influences the microbiome of the skin. There are noted variations in skin microbial communities between those living rurally and those in urban areas. There is also an increase in chemical use associated with urban living, which also influences the composition of the microbiome. Diversity is significantly reduced with the use of detergents and antibacterial cleaning products. Potentially pathogenic taxa are also increased as there are fewer good guys to keep the bad guys in check. This is why skin issues like acne or dermatitis are deemed western diseases; they simply just aren’t found on the skin of indigenous tribes or on that of individuals from non-industrialised societies. What is also interesting is that there is also a clear distinction between male and female microbiome, therefore suggesting hormonal influences. This poses food for thought in the neutered pet and how their microbiome is subsequently affected. Unnecessary use of antibiotics also affects the skin microbiome, along with excessive use of grooming products and of course nutrition. The Oral Microbiota There is a collection of microbes found in the mouth; these are the ones that result in bad breath or dental issues. Again, they pose a first line of defence against ingested potentially harmful pathogens. But they also play a role in metabolising certain nutrients. It is clear that the oral microbiota found in dogs differs significantly from humans – some researchers have even gone as far as saying that a human bite would be more dangerous than a dog bite in terms of wound infection potential. Findings here The oral microbiota is gaining more attention and for good reason – there are associations between oral microbiota composition and weight gain, much like we have with the gut microbiota. So, caring for the mouth cavity is just as important as caring for the gut, and colonisation, like in the skin occurs at and shortly after birth – and certainly within the teething period! Data is relatively new, but in human realms, to support oral health, the guidelines regularly include avoiding ultra-processed foods along with high-sugar foods (think high-fructose corn syrup found in many dog treats and processed foods). Guidelines also promote dental hygiene –for our puppies and dogs, raw, meaty bones are a great opportunity to support dental health. Remember to choose appropriately sized bones for puppies – soft bones like chicken necks or wings. They must always be raw – cooked bones pose a splinter risk! The Gut Microbiota/Microbiome When we reference the microbiome, we are considering the microbial community found in the whole of the digestive tract. Generally, the further down we go, the more bugs we find. SIBO or small intestinal bacterial overgrow this when there are too many bugs in the small intestine. We want the majority of them in the large intestine. Each puppy and dog have a unique microbiome – just as we do. It’s like a fingerprint. How cool is that? But it just goes to show that if there is dysbiosis (imbalance of good to bad guys) – there is no one silver bullet. For our puppy, we are in a great position to support optimal gut health from the beginning (not withstanding gene interactions). When we talk about the microbiota or microbiome, we are not just talking about bacteria, but fungi and viruses which live inside the gut too. This is totally normal – the good guys with the right tools can keep the bad guys in check. This community can metabolise nutrients (ruminant
Puppy Nutrition 101 The dog is unique amongst other mammals in that it has the widest range of normal adult body weight within one species. Many breeds will reach 50% of their adult size within 5-6 months. Some breeds will be fully grown by 8-12 months, some 12-18 months, and others 18-24 months. With this incredible range, it’s no surprise that puppyhood is in fact a very sensitive period, and one that we need to get right. Here at My Pet Nutritionist, we are incredibly lucky that we support many owners in choosing the right nutritional plan for their growing puppy. But we thought we’d compile a brief guide to some of the most important things to consider for the growing puppy. Growth and Development After nursing, post-weaning growth is the most nutritionally demanding period in a dog’s life. For large and giant breeds, the length and speed of their growth poses an even higher nutritional demand. By maturity, most dogs will have increased their birth weight by 40-50 times. How amazing is this? But it also poses something to be very conscious of. Physical Growth How are bones formed? Also known as ossification, bone formation is a process where new bone is produced. Look at any large breed and it is clear to see how much new bone needs to be produced from birth to full skeletal maturity. Bone starts as a cartilage model which gets slowly replaced. Osteoblasts are the cells that form new bone. They secrete osteoids. Osteoid tissue is simply unmineralised bone tissue. Soon after the osteoid is laid down,inorganic salts are deposited which forms the hardened material that we know as bone. These inorganic salts include calcium and phosphorus. Bone formation proceeds outwards from ossification centres; short bones tend to have one in the middle whereas long bones typically have three, one at each end and one in the middle. Ossification, or bone formation continues until there is a thin strip of cartilage left at each end of the bone. This is known as the epiphyseal plate, or growth plate in the dog world. When the bone reaches full adult maturity, the cartilage is replaced with bone and“sealed” for want of a better word. It is therefore no surprise that certain minerals are necessary for physical bone growth, along with some vitamins. Calcium is the most abundant mineral in the body; the majority of which is contained in the skeleton. Phosphorus is the next most abundant; also found in bone. Although they have separate functions within the body, being so closely interrelated, they are usually considered together. Calcium is involved in constriction and dilation of blood vessels, nerve impulse transmission, muscle contractions(including the heart), secretion of hormones and blood coagulation. It also plays a role in fluid balance in cells (contributing to homeostasis). A diet grossly inadequate in calcium, results in hypocalcemia. The body will remove calcium from bones to ensure normal cell function in the rest of the body. This leads to weakened bones. Hypercalcemia is a little more uncommon, but it is most often linked with overactive parathyroid gland function. Phosphorus is essential in cell growth and differentiation, energy use and transfer, fatty acid transport and amino acid and protein formation. In general, phosphorus is better absorbed from meat products than plant products. Phosphorus found in meat is mainly in its organic form; in plants it is in the form of phytic acid. Phytic acid impairs the absorption of iron,zinc and calcium and has been linked to mineral deficiencies. It is often referred to as an anti-nutrient. Deficiencies of calcium and phosphorus are unusual, but imbalance is noted. In unbalanced diets, calcium deficiency can develop alongside high levels of phosphorus. Low calcium levels stimulate the release of parathyroid hormone, which increases the production of the active form of Vitamin D. This results in an increased bone reabsorption to restore calcium levels. This eventually leads to bone demineralisation and a loss of bone mass. In dogs, this is more commonly noticed in the mandibles (jaw bones), leading to tooth loss and periodontal disease. Attention is most often paid to the calcium:phosphorus ratio. The note to make is that organic sources of both minerals are slowly and less efficiently absorbed; so, in fresh fed dogs this is less of a concern in terms of excess. Phosphorus found in meat products however is more efficiently absorbed than that found in plants. Findings here Other nutrients relevant to skeletal development include vitamin D, vitamin A, copper, zinc and manganese. Deficiency or excess in these have regularly been linked to abnormal orthopaedic development. But, as we know, it is not just the bones in puppies that grow – it is in fact every part of their body! What do puppies need to grow? Protein Proteins are large, complex molecules composed of hundreds to thousands of amino acids. They are literally the building blocks of the body. Protein is required in the diet to provide a source of amino acids to build, repair and replace body proteins. Proteins in the body have numerous functions. Major structural components of hair, skin, nails, tendons, ligaments and cartilage. Hormones are composed of protein molecules – these include insulin and glucagon which are key to maintaining blood sugar levels. Proteins are found in the blood– for example haemoglobin carries oxygen between the lungs and cells,lipoproteins carry fats throughout the body and transferrin carries iron through the blood. Proteins are also found in the immune system in the form of immunoglobulins to make the antibodies that provide resistance to disease. All proteins are in a constant state of renewal and degradation and during growth (or reproduction) additional protein is needed for the creation of new tissue. High rates of protein synthesis occur in: The production of red and white blood cells Epithelial cells of the skin and those lining the GI tract and pancreas Digestion of Protein Dietary amino acids are absorbed in the gastrointestinal tract, following disruption of their structure. They are then transported
The primary two functions of the skin is to act as a protective barrier and an immune barrier, between the body and its external environment, it keeps everything in, and prevents the entry of pathogens and allergens. Here at My Pet Nutritionist, we have heavily focussed on the skin function and allergies so let’s take a look. A defective skin barrier is a key feature of the chronic inflammatory skin disease, atopic dermatitis and it has been noted that the protein filaggrin has a pivotal role in skin barrier function. Mutations with the FLG gene, which encodes filaggrin, strongly predisposes to conditions including atopic dermatitis and secondary allergic diseases. Whilst we always find these revelations in human literature, we have found that this also applies to dogs. So, let’s take a look at filaggrin in a little more detail and how there is a possibility that the skin issues faced by your dog may have a genetic origin. What is Filaggrin The term filaggrin, derived from filament-aggregating protein, was first coined in 1981 to describe a class of structural protein that had been isolated from the stratum corneum (the outermost layer of the epidermis of the skin). Filaggrin is formed from the breakdown of profilaggrin, a protein contained in the granular layer of the upper epidermis. Filaggrin is vital for skin cells to mature properly into the tough, flat corneocytes that form the outermost protective layer of our skin known as the cornified cell envelope (CCE). It does this by binding together the rigid keratin filaments that form a structural skeleton within the cells. As a result, the cells collapse and become flattened. The CCE is constantly renewed by new cells formed in the basal layer of the epidermis. These gradually work their way to the top of the skin layers where they become corneocytes. They will then shed. Surrounding the corneocytes you will find a layer of lipids, which coat the CCE, keeping the skin waterproof, protected and supple. This also provides a protective layer, keeping out irritants and allergens. Without filaggrin, the CCE does not form correctly. Corneocytes dry out, and the lipid layer is lost. This results in dry, cracked skin and a permeability to the skin. Atopic dermatitis is characterised by these symptoms, and data has revealed an association between loss of functions of the filaggrin coding gene and this condition. In short, these conditions are more commonly noted in those with a mutant gene, than those without a mutant gene. What is particularly interesting is that the environment plays a role, not only in developing atopic disease, but also directly in FLG expression. It is regularly noted that exposure to irritants can reduce epidermal FLG levels and lead to an acquired filaggrin deficiency. The FLG deficiency, be it genetically determined or acquired, causes an altered epidermal structure and an impaired barrier function. Sadly, this allows penetration of environmental allergens into the skin, including house dust mites, pollen, bacteria, irritants, and toxicants but it also results in sensitisation of the host. The resultant alteration of the epidermis by way of increased pH, altered lipid secretion, modification of keratinocytes and reduction of antimicrobial peptides also then paves the way for the perfect environment for other bacteria and fungi to thrive, leading to recurrent skin infections, which you’ll have likely observed in cases of canine atopic dermatitis. Environmental and Inflammatory Factors known to alter the amount of Filaggrin: Humidity It seems there is a correlation between indoor humidity and disease severity. In human studies, in those children with atopic dermatitis and FLG mutations, their skin lesions are more often located in air-exposed skin areas. Interestingly, children with atopic disease experience a reduction in disease severity after one month spent in a humid climate. It seems that filaggrin and more filaggrin proteolysis is required in a dryer environment and for that reason, it is often concluded that children predisposed to atopic dermatitis should be encouraged to increase their indoor humidity. Findings here Mechanical damage Mechanical damage includes stretching, compression, and friction on skin cells. It not only affects the barrier function of the skin but also induces various immune responses, triggering inflammation at the site of the stress on the skin. For example, scratching of itchy lesions exacerbates the skin inflammation in atopic dermatitis. This increase in inflammatory mediators has been seen to down regulate filaggrin expression. Skin Irritants Studies have demonstrated that profilaggrin expression can be down regulated after application of experimental sodium lauryl sulphate (SLS). In the 6 hours post exposure, it was noted that SLS in fact induced skin barrier defects. Findings here SLS is what’s known as a surfactant. This means it lowers the surface tension between ingredients, which is why it’s used as a cleansing and foaming agent. You will find SLS in a range of human products and may find it in some dog grooming products. It is generally what makes them foam. Human Products: Hand sanitiser Makeup remover Liquid hand soap Shampoo Conditioner Styling gel Bubble baths Dental care products like toothpaste Anti-itch creams Sunscreen You may also find it as a food additive in certain products, it is used to mix acids with other liquids, or as an emulsifier or thickener. Dog Grooming Products: Shampoo Conditioner Detangler Conditioning balms Deodorising sprays Cologne It is also worth noting that some shampoos specifically prescribed or advertised for use in atopic disease also contain SLS, amongst other ingredients. The issue is that when products reduce filaggrin expression, it disrupts the skin barrier, making it permeable to other toxicants and irritants, creating a vicious cycle. What you choose to apply to your dog’s coat and skin is just as important as what you put into their body through their diet. Not only that, but whilst you may not be applying human products directly to your dog, they may come into contact with them through exposure to soft furnishings or you. In the hopes to create a mechanical barrier, without harsh chemicals being used, there are certain topical products
Constipation is the infrequent or difficult passage of faeces. As pet owners, we may pay more attention to the size, colour and consistency of bowel movements and not necessarily notice that our companion hasn’t “gone” for a while. The first hint we may notice is straining when out on a walk with our dogs, or our cat spending more time in the litter tray than usual. When they do go, faeces are dry and hard. Constipation is something that we are asked about regularly here at My Pet Nutritionist, so let’s take a look at what actually occurs in the digestive tract in cases of constipation, what can cause it, and some top tips for managing it. The Digestive Syste Unlike us humans, our pets lack salivary enzymes and so the digestion of their food doesn’t really start until it hits the stomach. As food travels down the oesophagus, it goes through a gateway known as the oesophageal sphincter before getting to the stomach. The stomach is like a washing machine, it churns the food and releases detergent-like compounds to break the food down. Food is turned into a smoothie like consistency known as chyme, which then makes its way to the small intestine. The small intestine is covered in tiny,carpet-like projections known as villi which are vital for nutrient absorption. In short, these villi allow the goodness found in the food to get to the rest of the body. But for that to happen, the chyme needs to be broken down further. Here is where the pancreas comes in. The pancreas is like a factory, it produces enzymes that help to digest food, along with hormones that help control how much sugar is in the blood too. The liver also produces bile acids which are secreted into the small intestine from the gallbladder to help with digestion and absorption of fat. Just to make sure digestion is targeted from all angles, the lining of the small intestine also contains enzymes that break down food too! After the small intestine has done its job, the unabsorbed bits (including fibre) move into the large intestine. But it must go through the ileal brake first. This is like a watchdog; if it spots under-digested food coming through, it tells the upper-gut movements to shut down their party. The large intestine also plays a role in nutrient absorption, simply because it houses trillions of microbes that can help digest things that have so far been indigestible. These microbes also produce messenger molecules to the brain, reducing inflammation and signalling satiety amongst other functions. The large intestine also reabsorbs fluid and electrolytes. During this process,the contents in the gut turn from liquid to solid, so the longer the food remains here, the more water is absorbed and therefore the more solid it is. Sloppy poops spend significantly less time here. At the end of the large intestine, the rectum stores and compacts the waste, before the brain receives the signal to release the accumulated waste though the anus. But how does food move through this system? As the intestine looks much like a computer game from the 1980s, we’re pretty sure gravity isn’t completely in charge. Well, it isn’t. The movement of food through the system is largely thanks to a carefully curated orchestra of muscle contractions. On of these programmes is peristalsis, which are wavelike contractions. Earthworms actually use this mechanism to drive their movement. The other is segmented contractions which generally occur in the small intestine. In the large intestine, mass movements propel the chyme/faeces towards the rectum. What is particularly interesting is that the gut can function independently of the brain, so it can do all of this without any conscious thought. Digestion forms part of the parasympathetic nervous system, appropriately dubbed rest and digest. This leads us into our first possible cause of constipation… Stress When the body feels stressed, resources are redistributed to organs and functions that need them. Sadly, the digestive system is not one of them. Stress can result in a temporary halt to digestive function (of course,stress can also result in projectile diarrhoea, but we never said the body was an easy study did we!). Without the nod to continue its work, waste can sit, waiting for the signal to release. Changes in Routine The digestive system also displays circadian rhythm variations. There is evidence that peristalsis has its own routine. Gastric emptying rates are slower in the evening, and the migrating motor complex (think of it as the road sweep after a car accident, clearing the small intestine between meals) is slower at night too! Not only that but the liver seems to have its own circadian regulation to synchronise with periods of feeding and fasting. Findings here Factors which inform circadian rhythm: Light Mealtimes Sleep Exercise Temperature If your pet has recently experienced changes to their mealtimes, walk times, or had disrupted sleep, this could play a role in their changing bowel habits. Dehydratio This is particularly relevant to cats. They historically have a low thirst drive and sadly, chronic kidney disease is a risk factor for constipation (diagnosis is increasing year on year). As we noted earlier, the large intestine reabsorbs fluid, and it is here that generally dictates how solid the poop is likely to be. The body always wants to maintain homeostasis, so it will always try to balance its levels. For the cat who isn’t gaining much moisture from their diet, there isn’t much water to reabsorb in the large intestine, but by gum, it will try! This is why we always advocate a fresh food diet for your pet. Always have fresh, filtered water available too. A worthwhile read on cats, hydration and kidney disease here. Obstruction Obstruction can be as sinister as it sounds, blockages caused by foreign objects like toys, plastic bags or elastic bands, but it can also be a medical obstruction caused by a tumour, abscess or granuloma. That said, as pets regularly groom themselves, they
