It’s strange to say a molecule is getting “press,” but that’s exactly what’s happening to NAD+ (nicotinamide adenine dinucleotide) in publications ranging from Wired to Shape. NAD+ (pronounced en-aye-dee) is an essential molecule found in every living cell. Biochemists have known about this critical coenzyme since 1906 and have extensively studied how all living cells use NAD+ to generate energy.

But newer research is expanding how scientists think about NAD+. We’ve learned that NAD+ can be used by cellular machines like sirtuins which help cells respond to stress and maintain their overall health. We also know NAD+ levels decline with age. Now the fact that we lose NAD+ over time and that it’s involved in so many different processes is precisely why some of the world’s leading neuroscientists, biochemists, and researchers are paying attention to it.

Here are just some of the ways we know NAD+ is involved in our body’s functions:

1. NAD+ and aging.

Out of all the factors that require NAD+, aging is probably the most significant and least avoidable. According to a study published in PLOS One, by age 60, a person’s NAD+ levels are approximately half of what they were in their 40s. This is simply because our cells make NAD+, and as we age our bodies can’t replace the cells that die as quickly with new ones. But even if we’re still young and healthy, everything listed below may contribute to this age-related decline in NAD+ as well. 

2. NAD+ and alcohol.

Whether you get your buzz out of grapes, barley, potatoes, or molasses, all alcohol is created from sugar. For our bodies to process that after-hours beverage, the alcohol must first be detoxified by enzymes that require NAD+ to function. According to a short communication published by Hugo Theorell and Roger Bonnichsen, NAD+ is involved in two steps of this process: first to detoxify the alcohol into sugar, and then to help that sugar turn into energy.

3. NAD+ and fat.

One of NAD+’s most essential functions is energy metabolism. Our cells use NAD+ to turn the food we consume into the energy we need to stay healthy. NAD+ does this by turning into the hydrogen-carrying version of itself (NADH) which aids in burning fats and proteins in the cell. 

4. NAD+ and carbs.

NAD+ also turns into NADH to help convert carbs into energy. This is because it plays an important role in glycolysis, the cycle by which our bodies convert sugars into energy. 

5. NAD+ and sleep.

The production of NAD+ is one of the many biological processes in our bodies that follows a circadian rhythm. Energy metabolism, hormone regulation, and body temperature variations all rely on a 24-hour cycle as well. NAD+ helps regulate circadian rhythms, keeping them all in sync and working at their best. Which is a good thing because misaligned circadian rhythms lead to things like jet lag and sleep deprivation.   

6. NAD+ and sunlight.

We’ve known for years that too much sun can definitely be a bad thing. But one of the reasons why that’s true is because of NAD+. According to a study published in Aging and Mechanisms of Disease, our cells use NAD+ to help activate sirtuin proteins and to create the cellular energy needed for responding to long-term sun exposure. 

7. NAD+ and muscles.

Strenuous exercise requires NAD+ for muscle recovery, while mice studies show that moderate or light exercise can actually increase NAD+ levels. 

8. NAD+ and sitting.

Even someone living a sedentary lifestyle requires NAD+ for basic biological functions like eating, sleeping, and breathing. 

9. NAD+ and breathing.

While our bodies need oxygen, the metabolism of oxygen can sometimes affect other parts of a cell through an imbalance known as oxidative stress. According to a review published in Free Radical Biology and Medicine, NADPH is an important part of the body’s defense against oxidative stress, oxygen metabolism depletes NADPH.

With NAD+ being involved in so many processes in our bodies, it’s easy to understand why scientists couldn’t really factor it into their research early. But now that they can safely increase and measure NAD+ levels, they’re looking into just how many ways this one molecule could improve human health, especially in older adults.

NAD (nicotinamide adenine dinucleotide) is a collective term for all the different forms NAD takes throughout the various chemical processes it takes in our body. However, you might find several supplement options that list NAD+ or NADH as the active ingredient. Is this different from NAD without the “+” symbol or “H” at the end?

Yes and No. Whenever someone uses the acronym NAD, what they are really encompassing is a process and not just one definitive molecule. NAD is found as two different molecular structures: NAD+ and NADH.

The transformation of NAD+ to NADH.

NAD+ and NADH are really depicting the same molecule undergoing a transformation. To illustrate this process, it’s best to observe NAD’s role in the mitochondria. Our mitochondria work hard to produce the energy our cells need to properly function. Mitochondria function like electric generators, commonly known as “the powerhouse of the cell”. NAD is a key component in this energy-making process. 

NAD is first introduced in this energy cycle as NAD+. NAD+ is what you might call the “raw” form of NAD. It simply acts as a vehicle. Creating NAD+ is like manufacturing the body of a pick-up truck. It’s brand new and doesn’t have any cargo in the truck bed. However, it will soon use its cargo space to carry forth critical components to the enzymes of the cell, including mitochondrial enzymes. 

NADH is what you might call the “loaded” form of NAD. Using the pick-up truck metaphor, NADH is like a truck with cargo. In this form, NADH is carrying a charged hydrogen molecule with two electrons. NADH’s primary purpose is to bring these charged electrons to the mitochondrial enzymes needed for the energy-making process. 

Notice that NADH does not carry the “plus sign”. This is because the positively charged hydrogen molecule cancels the positively charged NAD+ molecule. 

Once NADH arrives at the enzymes, they drop off their positively charged electrons and expel the hydrogen atom, subsequently becoming NAD+ again. The rest is taken care of by the enzymes. 

After the drop-off, NAD+ is now an empty pick-up truck again and is able to leave to collect more positively charged electrons. 

So what do you call it?

As NAD transports these positively charged electrons to the enzymes, it constantly changes back and forth between the forms NAD+ and NADH. So NAD’s molecular structure is solely based on what leg of the journey it currently sits. 

Therefore, it’s not really accurate to say your body needs more NADH since NADH doesn’t exist until NAD+ undergoes its second leg of its journey. When you see supplements that call themselves an NADH booster, it doesn’t really make sense since your cells use the micronutrients in the supplement to build the raw form of NAD first: NAD+. 

The key question is what ratio of NAD+ does your body need compared to NADH. 

While the optimal NAD to NADH ratio remains elusive, research suggests that a generally higher NAD to NADH ratio is favorable. A low NAD to NADH ratio has been linked to mitochondrial dysfunction and accelerated aging. 

When it comes to a plain NAD label, it’s not wrong to be identified as a NAD booster. Generating more NAD+ will naturally generate more NADH. However, the specificity of NAD+ is more indicative of what your cells are truly building when using NAD+ boosting supplements like Tru Niagen®.

Ever since the first human saw their reflection in water, we've sought to reverse—or at least hide—the effects of aging. Our efforts over the centuries to thwart aging have led us to some rather scary methods. The ancient Egyptians basically invented cosmetics, developing hair growth serums for men and night creams for women. Some even turned to leeches and crocodile dung as elaborate topical treatments designed to make them appear healthier and younger. Regularly self-poisoning with ammonia, arsenic, mercury, and lead were all part of many Victorian women’s daily routine. In the 15th century, a Hungarian noblewoman named Countess Elizabeth Báthory de Ecsed went so far as to bathe in human blood in a vain attempt to restore her youth.

While focusing on outward appearances may seem to be the easier way to combat aging, those attempts almost never address the root cause of what’s going on underneath our skin. Let's investigate the history behind the science of aging to better understand the aging process.

Chapter 1: Understanding aging as a biological process.

Age may be nothing but a number, but aging is a biological process. Also called “senescence,” aging is the gradual deterioration of our most basic functions. You don’t need to be a biogerontologist (a scientist who studies biological aging) to know that that deterioration goes much deeper than the skin.

The symptoms we associate with aging, like wrinkles, loose skin, and stiff joints, are all just outward signs of what is happening inside our bodies at a microscopic level. Our cells are, in fact, failing. Today, researchers are beginning to study just how much of that failure is due to the decay of strangely shaped organelles known as the mitochondria. 

Chapter 2: Exploring the work behind the mitochondria.

As the “powerhouses” of the cell, the mitochondria generate 90% of the energy our cells need to survive. They function like miniature, self-contained organs living and dying all while inside of our cells. But like any organism, the mitochondria rely on a power source to keep them charged. That source is an essential molecule known as NAD+ (nicotinamide adenine dinucleotide).

The story of NAD+’s discovery begins with beer. In the mid-19th century, Louis Pasteur collaborated with French brewers to study the microscopic forces at work during the brewing process. He identified “diseases” of beer—microbes that could cause the beer to spoil—as well as the important role that yeast played in the process of alcoholic fermentation.

In 1906, Arthur Harden and William John Young expanded Pasteur’s discovery of fermentation by investigating the process that yeast used to turn sugar into alcohol. To get under the hood, they cracked open yeast cells and separated the cellular components into two mixtures.

One mixture contained the enzymes needed for fermentation and the other contained several small molecules. Though they didn’t know it at the time, this small molecule mixture contained NAD+. And it was vital for the process of alcoholic fermentation to proceed.

While this discovery helped establish NAD+’s essential role in beer making, it was not quite an anti-aging breakthrough. A deeper understanding of just how crucial NAD+ is to our mitochondria wouldn’t begin for another 40 years. Because like most great discoveries or innovations, understanding the role healthy cells play in aging was a long and non-linear process, with many bumps in the road along the way. 

Chapter 3: Discovering the properties of NAD+.

In 1929, a former art student continued Harden and Young’s work. Hans von Euler-Chelpin studied the details of the reactions that happened during yeast fermentation. In his work, he was actually able to separate the components of this process into their individual parts, essentially “purifying” NAD+. Euler-Chelpin is also credited with uncovering the first insights about NAD+’s chemical shape and properties, laying the foundation for all future research surrounding this vital molecule.

By 1936, Otto Heinrich Warburg had uncovered that NAD+ was an essential part of yet another crucial chemical reaction: hydride transfer. Warburg was also studying fermentation when he realized the hydride transfer process, which is essential to cellular metabolism, used NAD+. Hydride transfers happen any time there’s an exchange of a hydrogen atom and its accompanying electrons. Warburg’s research showed that the N (nicotinamide) which accepts the hydride in NAD+’s molecular makeup was the primary reason this process was able to occur and move forward in the first place. 

Pellagra had disrupted the nation since the early 1900s. This disease, also known as “the black tongue” in dogs, caused symptoms such as dermatitis, diarrhea, and dementia in people of all ages. Although Joseph Goldberger had identified pellagra as a nutritional deficiency, his experiments leading to that discovery were more than controversial. In 1938 Conrad Elvehjem continued this research by conducting his own somewhat controversial experiments and found that nicotinic acid, a form of vitamin B3, cured pellagra in dogs.

Nicotinic acid, also known as niacin, would eventually be used as a vitamin supplement to cure pellagra in humans. But it’s only one example of how vitamins would enhance healthy aging for years to come.

Chapter 4: Connecting vitamins to NAD+.

Today, there are plenty of lists online about the kinds of foods, drinks, or supplements we can take to help our cells acquire these essential vitamins that are vital for preventing diseases like pellagra, scurvy, and rickets. These vitamins prevent these deficiencies by acting as “precursors" for essential cellular molecules.

A precursor is a compound that can create another compound through a biochemical reaction. Vitamin K begins the chain reaction in our cells so our blood can clot, vitamin A kick-starts the nervous system response that gives us sight, and vitamin B begins the process of turning food and drinks into energy. Without these vitamin precursors, our cells can’t perform those basic everyday functions we sometimes take for granted. 

In 1940, Arthur Kornberg drew on the research of those before him to narrow down exactly which vitamins served as precursors to NAD+. He combined Euler-Chelpin’s work of “purifying” NAD+ to its most basic form and Conrad Elvehjem’s discovery that nicotinic acid cured pellagra. He separated NAD+ and recombined it with other isolated components to replicate the chemical reaction he hypothesized was already taking place in our cells. And as such, discovered the first known vitamin precursor to NAD+. 

Chapter 5: Investigating NAD+ more seriously.

After replicating the creation of NAD+, Kornberg’s predecessors attempted to breakdown the process even more. The Preiss–Handler pathway was discovered by two guys named, Jack Preiss and Philip Handler. These two showed that nicotinic acid is converted into NAD+ in three steps, and identified the proteins and enzymes responsible for them.

In 1963, Paul Mandel of the University of Strasbourg’s Institute of Biochemistry further advanced this quest. His work identified a reaction that actually broke NAD+ into two separate parts: nicotinamide and ADP-ribose. Mandel’s findings led biochemists to better understand just how essential NAD+ is to energy metabolism in the cell, and therefore to the mitochondria themselves.

All of these studies may seem rather arbitrary, but each discovery fed into and informed those that followed. These findings would eventually draw modern researchers to the mitochondria as a way to better understand healthy aging. Especially once a group of “longevity proteins” got involved.

Chapter 5: Using sirtuins to study longevity.

At the start of the 21st century, scientists were studying yeast fermentation again. They found some of these seven proteins known as sirtuins were responsible for extending lifespan in yeast. Researchers began to wonder, if sirtuins could expand the life of yeast cells, would they be able to do the same for humans?

Although they still don’t have the clinical trials to support this hypothesis yet, researchers see a lot of promising results in the past studies surrounding yeast and mice. They found some sirtuins affect longevity because they use NAD+ to help keep certain genes “silent,” or non-functional. When sirtuins are active and thriving, these “gene silencers” encourage cellular health in yeast and mice.

Sirtuins and NAD+ work together to:

• Regulate circadian rhythm: The Sirt1 affects gene function, which in turn can help the body’s many circadian rhythms stay in sync.

• Increase energy metabolism: Sirt1 deals in energy metabolism and Sirt3 is an essential part of the citric acid (or Krebs) cycle. Both of which are an integral part of turning food and drinks into energy.

• Maintain a healthy nervous system: NAD+ supports the body’s normal response to inflammation by activating Sirt1.

Whenever we stress our bodies to the point where they need sirtuins, NAD+ goes into overdrive. If we do too many of those things at once or without replenishing those NAD+ levels first, there might not be enough NAD+ to go around. Meaning sirtuins may not have full access to all their resources in order to help us stay healthy. 

Chapter 6: The future of healthy aging.

Age itself is inevitable. Defects are written into our DNA before we’re born. There’s nothing wrong with turning to trustworthy topical treatments to address the outward effects of aging. But if we really want to figure out what’s going on, it helps to remember why we see those signs in the first place: our cells.

Scientists now know that our cells use NAD+. But they’ve also learned that NAD+ levels decline over time and under stress. So everyday things like eating too much and drinking alcohol can deplete our body’s natural NAD+ resources. Basic cellular functions are left to fight over a dwindling supply of NAD+ that only gets smaller as we age.

According to research published in Slate, lifespans have been on the rise for decades. So what are we supposed to do with all this extra time we’re accumulating? With NAD+ supplements in our arsenal, the real question is what are we going to do with all this newly restored health and vitality? The answer from our bodies is clear: Thrive.