Macronutrients, or "macros," are essential nutrients your body needs in significant amounts for optimal function. The three main macronutrients—carbohydrates, protein, and fat—play unique roles in maintaining your body's structure and processes, providing energy and supporting overall health.

What Are Macronutrients?Macronutrients are nutrients your body requires in large quantities:

- Carbohydrates

- Proteins

- Fats

These are considered essential nutrients because your body cannot produce them or cannot produce them in sufficient quantities. Each macronutrient is found in a variety of foods:

- Carbohydrates: Whole grains (oats, brown rice), starchy vegetables (potatoes, peas), fruits (bananas, apples), beans, and dairy products.

- Proteins: Meat (chicken, beef), seafood, eggs, soy products (tofu, tempeh), legumes, nuts, and seeds.

- Fats: Avocados, nuts, seeds, fatty fish (salmon), cooking oils, and full-fat dairy products.

Many foods provide a mix of macronutrients. For instance, dairy offers both protein and fat, while legumes contain protein and carbs.

Each macronutrient serves specific roles:

Carbohydrates are the body’s preferred source of energy, essential for fueling the brain, central nervous system, and muscles during daily activities and exercise. During digestion, carbohydrates are broken down into glucose, which provides immediate energy for the body. Excess glucose is stored as glycogen in the muscles and liver, forming a reserve that can be drawn upon during fasting or strenuous physical activity. Beyond energy production, dietary fiber—a type of carbohydrate that isn’t broken down during digestion—plays a crucial role in digestive health. Fiber promotes regular bowel movements, prevents constipation, and helps you feel full after meals, supporting weight management and overall well-being.

Proteins are vital for growth, repair, and maintenance. Composed of amino acids, they are the fundamental building blocks for muscles, tissues, and organs. Proteins repair damaged tissues and play a key role in muscle development, making them essential for physical recovery and strength. Beyond their structural functions, proteins are integral to the formation of enzymes and hormones, which regulate numerous bodily processes, from digestion to mood stabilization. Additionally, proteins contribute to the structural integrity of cell membranes, hair, skin, and nails, underscoring their importance in maintaining both function and appearance.

Fats serve diverse roles in the body, making them much more than an energy source. They are a critical component of cell membranes, maintaining their structure and facilitating communication between cells. As an energy reserve, fats provide a concentrated source of calories, ensuring the body has access to fuel during periods of low calorie intake or extended physical exertion. Fats are also indispensable for the absorption of fat-soluble vitamins such as A, D, E, and K, which are vital for vision, bone health, immune function, and antioxidant activity. Moreover, stored fat insulates the body, regulates temperature, and cushions organs, offering protection against external shocks and injuries.

Macronutrients vs. Micronutrients

Understanding the roles and sources of macronutrients can help you maintain a balanced diet tailored to your body's needs. By incorporating a variety of nutrient-rich foods, you can achieve optimal health and well-being.

Delhi’s air quality remained in ‘very poor’ category and a thick layer of fog also took over the city. As of 6am, the Air Quality Index or AQI stood at 385. On Monday, the AQI of the city stayed under the ‘severe’ category, and the overall 24-hour average was at 401. The India Meteorological Department (IMD) recorded that the general visibility of Delhi at 6.30am was 350 meters. The IMD also issued a fog alert for December 29 and the morning of December 30. Warning is also extended for neighboring states, including Haryana, Uttar Pradesh, Chandigarh, Punjab, and parts of Northeast, East, and North India.

The IMD on X wrote: “Dense to very dense fog is expected tonight and into the morning of 30th December across several regions including Haryana, Chandigarh & Delhi, Punjab, Uttar Pradesh, and parts of the Northeast, East, and North India. Visibility may be severely reduced, making travel risky. Please drive slowly, use fog lights, and avoid unnecessary journeys.”

Also Read: Is Delhi's Toxic Air Making You Sad And Grumpy? Here's What The Study Says

Pollution Could Harm Your Brain

While we all know the harm pollution could do to your lungs, doctors have also highlighted that pollution could also lead to cognitive ailments. Mental health impacts such as risk of depression, anxiety, ADHD, and neurodevelopmental disorders in children could rise.

Dr Deepika Dahima, a psychologist at AIIMS Delhi said that pollution could put mental health at risk. Prolonged exposure to fine particulate matter like PM10 or PM2.5 could lead to a rise in anxiety, depression, cognitive impairment and chronic stress. Children also show disrupted neural development and learning difficulties, while adults experience irritability, emotional fatigue and impaired decision-making.

Another medical practitioner, Dr Jitender Nagpal, deputy medical superintendent and pediatrician at Sitaram Bhartia Institute of Science, speaking to the news agency PTI said, “Increasingly, a wide spectrum of behavioural and learning issues such as attention difficulties, irritability, and poor academic performance are being noticed in many children.”

Studies too have linked the exposure of particulate matter or PM2.5 with increased ADHD risk. There are research that show a 1.51 fold increase per 5 μg/m³ increase in PM2.5 and others indicating elevated risks when exposure exceeds 16 μg/m³.

Another study published in December 18, in the journal Environmental Research by Oregon Health & Science University, found that everyday exposure to urban air pollution gradually alters brain development in children and young adults. The researchers of the Oregon Health & Science University discovered that exposure to air pollutants at ages 9 to 10 was associated with changes in cortical thickness in the frontal and temporal brain regions that are responsible for executive function, language, mood regulation, and socioemotional processing.

Another study published in Nature Communication notes that after four hours of exposure to particulate matter, it was found that people's ability to perform routine tasks and interpret emotions were highly impacted.

Study's co-author, Dr Thomas Faherty said, "Study provides compelling evidence that even short-term exposure to particulate matter can have immediate negative effects on brain functions essential for daily activities.”

Can Alzheimer's be completely reversed? This is not just about preventing it or ensuring it that the disease slow down, but can it be reversed to achieve full neurological recovery? For the longest, we have known that Alzheimer's is a progressive, degenerative brain disease, which destroys memory, thinking, and eventually the ability to perform simple tasks, but now a team of researchers from Case Western Reserve University, University Hospitals (UH), and Louis Stokes Cleveland VA Medical Center has challenged this belief. They may have found out something that could reverse it, at least so says the animal model.

Instead of targeting plaques or tangles alone, the team looked at something more fundamental: the brain’s energy system.

Their findings, published in Cell Reports Medicine, suggest that restoring the brain’s energy balance may not just slow Alzheimer’s but potentially reverse key features of the disease, at least in animal models.

What Did The Study Find?

The study is led by Kalyani Chaubey from the Pieper Laboratory, and at the center of the study is NAD+, a molecule essential for cellular energy and repair.

NAD+ levels naturally decline with age across the body, including in the brain. When levels drop too low, cells struggle to perform basic functions and eventually fail.

The researchers found that this decline is far more severe in the brains of people with Alzheimer’s. The same sharp drop was also seen in mouse models of the disease, pointing to a shared biological problem.

How the study was conducted

While Alzheimer’s is uniquely human, scientists use specially engineered mice to study it. In this study, two types of mice were used. One model carried human mutations linked to amyloid buildup, while the other carried a mutation affecting the tau protein.

Both amyloid and tau are central to Alzheimer’s pathology. Over time, these mice developed symptoms similar to human Alzheimer’s, including brain inflammation, damage to nerve fibers, breakdown of the blood-brain barrier, reduced formation of new neurons, and severe memory and learning problems.

Restoring energy balance in diseased brains

After confirming that NAD+ levels were dramatically reduced, the researchers tested whether restoring this balance could help. They used a drug called P7C3-A20, developed in the Pieper Laboratory, which supports cells in maintaining healthy NAD+ levels under stress.

Remarkably, the results went beyond prevention. Even when treatment began after significant disease progression, the mice showed reversal of major brain damage. Cognitive function fully recovered in both mouse models, despite their different genetic causes.

Biomarkers and what they signal

The recovery was not just behavioral. Blood levels of phosphorylated tau 217, a biomarker now used clinically in humans to detect Alzheimer’s, returned to normal in treated mice. This provided objective evidence that disease processes had been reversed, not merely masked.

Why this matters for people

The findings suggest a possible paradigm shift. Alzheimer’s damage may not always be permanent. Under certain conditions, the brain appears capable of repairing itself and regaining function.

However, the researchers caution against self-medicating with over-the-counter NAD+ supplements. Some have been shown in animal studies to raise NAD+ to unsafe levels that may increase cancer risk. The drug used in this study works differently, supporting balance rather than excess.

A newly recognised form of diabetes is reshaping how scientists and doctors view the condition, particularly in countries like India. In 2025, global health authorities officially acknowledged Type 5 diabetes as a separate and distinct form of the disease.

This recognition ended decades of confusion around a type of diabetes that did not fit neatly into the existing categories of Type 1 or Type 2 diabetes. The formal classification, backed by the International Diabetes Federation and supported by research published in The Lancet Global Health, is expected to transform diagnosis, treatment, and long-term care for millions of people worldwide.

But what exactly is Type 5 diabetes, and how does it differ from the types of diabetes that are more widely known?

What Is Type 5 Diabetes?

Type 5 diabetes is now recognised as a distinct form of the disease caused primarily by severe, long-term malnutrition, often experienced during childhood. This undernutrition can lead to profound insulin deficiency and an underdeveloped pancreas, resulting in significantly reduced insulin production.

Unlike Type 1 diabetes, which is autoimmune, or Type 2 diabetes, which is linked to insulin resistance, Type 5 diabetes arises from nutritional deficiencies that impair the pancreas’s ability to function properly.

It most commonly affects lean young adults in low-income regions. For years, people with this condition were misdiagnosed as having Type 1 diabetes or an unusual form of Type 2, often leading to inappropriate treatments that failed to address the root cause.

Type 5 Diabetes Symptoms

Symptoms of type 5 diabetes can resemble those seen in other forms of diabetes, such as excessive thirst, frequent urination, persistent tiredness, unexplained weight loss, blurred vision, and slow-healing wounds. However, they are often paired with indications of malnutrition, including a lean physique, delayed growth or puberty in young people, anemia, and recurring infections.

These arise from nutritional deficiencies during early life rather than solely from insulin resistance or autoimmune causes, and they usually present before the age of 30, according to the International Diabetes Federation.

Type 5 Diabetes: Scientists Demand Recognition

Researchers have been studying this condition for decades, particularly in parts of Asia and Africa. Yet, without official recognition, the disease remained poorly understood, and patients were rarely diagnosed correctly. Experts argued that grouping these patients under existing categories obscured the true cause of their illness.

The 2025 classification now formally separates Type 5 diabetes from other types, making it easier to study, identify, and manage. In India, where diabetes prevalence is already high, this recognition is particularly relevant. Tens of millions of people live with diabetes in the country, many of whom remain undiagnosed. Type 5 diabetes highlights a different pattern: it develops not from excess calories, but from too little nutrition during childhood, creating a double burden in regions where obesity and undernutrition coexist.

Implications for Diagnosis and Care

Although there is no new treatment specifically for Type 5 diabetes yet, official recognition marks a major step forward. Doctors can now approach lean patients with a history of malnutrition more carefully, avoiding a “one-size-fits-all” approach. Clearer classification could lead to better guidelines, more personalised care, fewer complications, and improved long-term outcomes.

Experts believe that understanding the role of childhood undernutrition in diabetes could eventually reshape how we prevent, monitor, and manage the condition—something countries like India urgently need as diabetes numbers continue to rise.