Part of the brain that controls blood pressure

In a world first, Prof Vaughan Macefield has developed a technique to measure how the brain controls blood pressure in health and disease.

What are you investigating here?

Part of the brain that controls blood pressure

Prof Vaughan Macefield

The volunteer in the MRI machine (pictured) has high blood pressure due to obstructive sleep apnoea (OSA). I have inserted a fine needle microelectrode into a nerve in his leg which is attached to the wires you can see just below his knee.

This microelectrode measures the vasoconstrictor signals that his brain is sending to his blood vessels to make them constrict and increase his blood pressure.

Once we have set up the volunteer, which we do in the lab and wheel him or her to scanner, I will take images of his brain with the MRI at the same time as recording the vasoconstrictor nerve signals through the microelectrode. This allows me to see which areas of the brain are sending these signals, and therefore which areas of the brain are controlling blood pressure. With these two measurements, I can get a very clear picture of how the brain is controlling blood pressure in both healthy subjects, and in those with cardiovascular disease.

Why is it important to know what areas of the brain control blood pressure? 

Blood pressure needs to be kept constant – too low and we faint, too high and we may suffer a stroke. We know that diseases such as obstructive sleep apnoea – in which collapse of the upper airways during sleep cause repetitive episodes of low blood oxygen – also cause changes to the brain, affecting memory, for example. We have also shown that there are structural and functional changes in the brain in people with OSA, changes that cause the increase in vasoconstrictor drive that leads to hypertension. We have just finished a study that followed 20 volunteers with OSA over a year, showing that the structural and functional changes we saw in the brain are essentially reversed by treatment with continuous positive airway pressure (CPAP).

Now that we know what is happening in the brain in OSA, we want to look at other forms of high blood pressure, such as renovascular hypertension. This is the basis of a new NHMRC grant we have submitted, in which we will be recording the vasoconstrictor nerve signals, at the same time as imaging the brain, to identify changes in the brain before and after treatment. Renovascular hypertension is brought about by narrowing of the arteries to the kidneys, and is treated by balloon distension of the artery or placing a stent in the artery. Ultimately, if we are able to better understand what damage occurs in areas of the brain controlling blood pressure, this may lead to the development of new treatments aimed at reversing some of this damage, thereby improving the blood pressure and the health of people living with cardiovascular disease.

What diseases interest you the most as a researcher?

As a basic scientist, there are many diseases that I see as “nature’s models” for scientific investigation, allowing us to understand disturbed physiology and compare it to normal physiology. It is only by understanding the two together will we be able to understand the processes that lead to pathophysiology. In order to undertake this work, I establish productive collaborations with clinicians, such as Prof David McKenzie, who provide us with patients with OSA.

Part of the brain that controls blood pressure

Hypertension is a circulatory disease. All parts of the body depend on the circulation, and many organs suffer from the impact of untreated hypertension. One of the organs at greatest risk is the brain.

What is blood pressure?

Blood pressure is the vital force that propels oxygen-rich blood to all parts of your body. Your heart is the pump that generates the force, and your arteries are the channels that transport and distribute the blood.

The height of your blood pressure is determined by how forcefully your heart's main pumping chamber, the left ventricle, contracts, and by the diameter and stiffness of your arteries. In turn, your heart and arteries are influenced by a large number of genetic, hormonal, metabolic, neurological, psychological, and lifestyle factors that determine your blood pressure. Because these influences are so numerous and complex, your blood pressure can vary from minute to minute and hour to hour during the course of the day, to say nothing of the slower shifts that occur over the course of a lifetime.

Blood pressure has two components. Your systolic blood pressure is the higher number, recorded while your heart is pumping blood into your arteries; your diastolic blood pressure is the lower number, recorded when your heart is relaxing and refilling with blood between beats. Both numbers are calibrated in millimeters of mercury (mm Hg), a vestige of the mercury column used in the first pressure manometers more than 100 years ago. By convention, the higher number is recorded first; a systolic pressure of 110 mm Hg and diastolic pressure of 70 mm Hg would be written as 110/70 and pronounced "110 over 70."

In adults, normal blood pressure means you have readings below 120/80. According to the newest guidelines, a systolic blood pressure between 120 and 129 is known as elevated blood pressure.

Stage 1 high blood pressure (a diagnosis of hypertension) is now between 130 and 139 systolic or between 80 and 89 diastolic (the bottom number). Stage 2 high blood pressure is now equal to or higher than 140 systolic or 90 diastolic.

Hypertension is also enormously consequential; in fact, it contributes to one of every six deaths in American adults. Because it involves the heart and blood vessels, hypertension is classified as a cardiovascular disease. But since arteries are vital to the health of all our organs, hypertension is actually a multisystem disease. In many cases, hypertension's most damaging impact does not fall on the heart but on the eyes, the kidneys, and especially the brain.

Stroke

There are two major types of strokes, ischemic and hemorrhagic (see illustration). Hemorrhagic strokes are less common but often cause the most dramatic symptoms. They occur when a blood vessel in the brain bursts, spilling blood into the brain or the fluid that surrounds it.

Ischemic strokes, which account for about 87% of all strokes, result when an artery that supplies blood to the brain becomes blocked by a clot. This can happen in either of two ways. In a thrombotic stroke, the clot forms in a diseased artery within the brain itself. In an embolic stroke, the clot forms outside the brain, then breaks away and is carried by the blood to the brain, where it lodges in a previously normal artery. Most emboli originate on atherosclerotic plaques in the carotid artery or aorta, or in the heart itself.

Each of these major types of strokes has a milder counterpart. Although major hemorrhagic strokes are impossible to overlook, MRI studies show that small microbleeds are much more common. Similarly, many people have tiny ischemic strokes, which are classified as lacunar strokes because of their small size. Although a simple microbleed or lacunar stroke is not likely to produce symptoms, a series of these events can produce major problems, including memory loss, or cognitive dysfunction (see below). These "silent" strokes are particularly common in people over 60, especially if they have hypertension.

Types of stroke

Part of the brain that controls blood pressure

Hemorrhagic stroke

  • 13% of strokes
  • Caused by ruptured blood vessels, followed by blood leaking into tissue
  • Usually more serious than ischemic stroke

Subarachnoid hemorrhage

  • Bleeding into the space between the brain and the skull
  • Develops most often from an aneurysm, a weakened, ballooned area in the wall of an artery
  • Severe headache is often the first symptom

Intracerebral hemorrhage

  • Bleeding from a blood vessel inside the brain
  • Often caused by high blood pressure and the damage it does to arteries

Ischemic stroke

  • 87% of strokes
  • Caused by blockages in brain blood vessels
  • Brain tissue dies when blood flow is blocked

Embolic stroke

  • Caused by emboli, blood clots that travel from elsewhere in the body to blood vessels in the brain
  • 60% of all strokes in Americans are embolic strokes; 25% of embolic strokes are related to atrial fibrillation (an irregular heart rhythm)

Thrombotic stroke

  • Caused by thrombi, blood clots that form where an artery has been narrowed by atherosclerosis
  • Also known as atherothrombotic stroke

High pressure, high risk

High blood pressure is the leading cause of strokes, both symptomatic and silent. Both systolic and diastolic hypertension contribute to risk; the higher your pressure, the higher your risk. According to one Harvard study, hypertension increases a man's risk of stroke by 220%; according to another, each 10 mm Hg rise in systolic pressure boosts the risk of ischemic stroke by 28% and of hemorrhagic stroke by 38%.

That's the bad news. The good news is that treating hypertension is extremely protective; in round figures, if you reduce your systolic blood pressure by 10 mm Hg, you should cut your risk of stroke by a whopping 44%.

Losing it

Mental decline is one of the most feared consequences of aging. But although many senior citizens experience some changes in memory as they grow older, most men who remain healthy continue to function at high levels. They learn to compensate for minor changes in the speed of recall and to use the wisdom that has accumulated over the years to maintain the ability to reason and think creatively.

Unfortunately, many men don't stay healthy, and many develop cognitive dysfunction. A variety of illnesses and medications can contribute to cognitive dysfunction — and as research continues to come in, it's increasingly clear that hypertension takes a toll on the aging brain.

Mild cognitive impairment can be a problem, but it's usually quite manageable. But severe memory loss is a disaster; you may think of it by its old name, senility, but doctors now use the term dementia to characterize these severe disturbances of memory, reasoning, and judgment. Although dozens of neurological diseases can cause dementia, just two account for the lion's share, multi-infarct or vascular dementia and Alzheimer's disease.

Multi-infarct dementia occurs when small vessels in the brain become diseased or blocked, depriving brain cells of the oxygen and glucose they need. If enough nerve cells are damaged or killed by the process, memory can't be restored.

Alzheimer's disease is different. The condition is associated with the accumulation of tau protein and beta-amyloid that form neurofibrillary tangles and plaques in the brain. In many cases, the part of the brain that is responsible for memory (the hippocampus) is hit the hardest.

One size does not fit all

Patients with hypertension often have additional medical problems that influence the choice of a blood pressure medication. Here are some conditions that may benefit from a specific class of medication; in every case, a physician should choose the medication that's best for that particular patient.

Compelling indicators for blood pressure drugs

Condition

Useful medications

Diabetes

ACEI, ARB

Previous heart attack

BB, ACEI, ARB

Previous stroke

Diuretic, ACEI, ARB

Kidney disease

ACEI, ARB

High risk of coronary artery disease

Diuretic, BB, CCB, ACEI, ARB

ACEI = angiotensin-converting–enzyme inhibitor

BB = beta blocker

ARB = angiotensin-receptor blocker

CCB = calcium-channel blocker

High pressure, short memory

Since hypertension damages blood vessels, it's easy to see how it contributes to vascular dementia. Although the link to Alzheimer's disease is less obvious, research suggests that vascular damage and tissue inflammation accelerate injury.

The details vary from study to study, but the weight of evidence now suggests that high blood pressure increases the risk of mild cognitive impairment, vascular dementia, and even Alzheimer's disease. Both systolic and diastolic hypertension take a toll; in general, the higher the pressure and the longer it persists without treatment, the greater the risk.

Most investigations focus on older adults. For example, a study of 2,505 men between the ages of 71 and 93 found that men with systolic pressures of 140 mm Hg or higher were 77% more likely to develop dementia than men with systolic pressures below 120 mm Hg.

Doctors may be able to help ease the burden of dementia, but the damage and disability cannot be reversed. That makes prevention doubly important. Can treating hypertension help prevent dementia?

Yes. European scientists reported that long-term antihypertensive therapy reduced the risk of dementia by 55%. Several American studies are only slightly less optimistic. One linked therapy to a 38% lower risk. Another reported that each year of therapy was associated with a 6% decline in the risk of dementia; in particular, men treated for 12 years or more enjoyed a 65% lower risk of Alzheimer's disease than men with untreated hypertension.

Never too late

It's good to know that blood pressure control can reduce the risk of cognitive dysfunction. But what about men who already have mild memory loss? Can treating hypertension help stave off further damage?

Perhaps. Italian scientists studied 80 patients with mild cognitive dysfunction. Over a two-year period, patients who were given antihypertensive medications were 80% less likely to progress to full-blown Alzheimer's than untreated patients. It's only one study, and a small one at that.

Getting control

For your head as well as your heart, get your blood pressure down. And even if you forget that hypertension is bad for your brain, remember that men with normal blood pressures live about five years longer than hypertensive men.

The first step is to know your blood pressure. The next step is to know your goal. Third, live right. Lifestyle modification can lower your blood pressure. It's an essential part of prevention and treatment of high blood pressure. Here are five steps that can help:

1. Diet. Reduce your sodium intake to less than 2,300 mg a day; 1,500 mg is the new, though stringent, goal for people with hypertension and for totally healthy folks who are middle-aged and older. Reduce your intake of animal fat and processed foods, but chow down lots of fruits, vegetables, whole grains, and fish. A good diet can lower systolic blood pressure by 10 to 22 mm Hg.

2. Exercise. Moderate exercise is excellent, even outperforming intense exercise in some studies. Walking for 30 minutes a day is one way to lower your systolic pressure by 4 to 9 mm Hg or more.

3. Weight control. Diet and exercise will get you there. An obese person who sheds 20 pounds can expect a drop of 5 to 20 points in blood pressure over and above the benefits of diet and exercise.

4. Limit alcohol use. Light to moderate drinking to the tune of no more than one drink a day won't raise your blood pressure, but heavy drinking will.

5. Use nonsteroidal anti-inflammatory drugs (NSAIDs) judiciously. Long-term use of NSAIDs (ibuprofen, naproxen, others) can raise blood pressure, particularly in older people.

6. Stress control. It's easier said than done in today's hectic world, but winding down can help you keep your pressure down.

When medication is needed, doctors most often start with a thiazide diuretic, ACE inhibitor, angiotensin-receptor blocker, or calcium-channel blocker. An alternative is to prescribe a combination pill that contains two blood pressure lowering drugs, both at low doses. 

Cooperate with your family to improve your lifestyle, and work with your doctor to find the medication that will bring you to your target blood pressure safely. It will take patience and persistence, but it's the brainy thing to do.

Does medulla oblongata control blood pressure?

Several forms of experimental evidence gathered in the last 37 years have unequivocally established that the medulla oblongata harbors the main neural circuits responsible for generating the vasomotor tone and regulating arterial blood pressure.

What part of the brain controls blood pressure and respiration?

Medulla. At the bottom of the brainstem, the medulla is where the brain meets the spinal cord. The medulla is essential to survival. Functions of the medulla regulate many bodily activities, including heart rhythm, breathing, blood flow, and oxygen and carbon dioxide levels.