Changing stroke rehab and research worldwide now.Time is Brain! trillions and trillions of neurons that DIE each day because there are NO effective hyperacute therapies besides tPA(only 12% effective). I have 523 posts on hyperacute therapy, enough for researchers to spend decades proving them out. These are my personal ideas and blog on stroke rehabilitation and stroke research. Do not attempt any of these without checking with your medical provider. Unless you join me in agitating, when you need these therapies they won't be there.

What this blog is for:

My blog is not to help survivors recover, it is to have the 10 million yearly stroke survivors light fires underneath their doctors, stroke hospitals and stroke researchers to get stroke solved. 100% recovery. The stroke medical world is completely failing at that goal, they don't even have it as a goal. Shortly after getting out of the hospital and getting NO information on the process or protocols of stroke rehabilitation and recovery I started searching on the internet and found that no other survivor received useful information. This is an attempt to cover all stroke rehabilitation information that should be readily available to survivors so they can talk with informed knowledge to their medical staff. It lays out what needs to be done to get stroke survivors closer to 100% recovery. It's quite disgusting that this information is not available from every stroke association and doctors group.

Saturday, August 5, 2023

The Argument for Grip Strength as a Vital Sign

Well, since my doctors and therapists completely fucking failed to get my left arm/hand recovered my left hand strength is still way behind. But my right probably makes up for it. Does that count? 

You doctor has known about this for four years. Did they competently create hand recovery protocols?

The Simple Sign That Your Brain Is Healthy - hand grip May 2019

 

Do you prefer your doctor and hospital incompetence NOT KNOWING? OR NOT DOING anything on this?

The latest here:

The Argument for Grip Strength as a Vital Sign

Most people hear "firm handshake" and automatically think "business world." A cursory search reveals articles with titles like "Seven Super-Revealing Things Your Handshake Says About You" (Forbes) and "How a Handshake Can Tell You Everything You Need to Know About a Person" (Inc).

Those in the know, however, understand what a handshake really reveals: Current health and vitality. The amount of force you can generate with your hand is a valid proxy for total-body strength. And total-body strength is one key to healthy aging.

Body temperature, weight, heart rate, and blood pressure inform any patient appointment. Should physicians include grip strength in that group?

Grip-strength testing is easy, fast, and noninvasive. It can be monitored over time. All it requires is a handgrip dynamometer, a tool that may cost less than a stethoscope, and a chair.

"Many studies have looked at strength as a predictor of positive health and weakness as a predictor of negative health outcomes," says Mark Peterson, PhD, an associate professor at the University of Michigan who's worked on dozens of those studies.

Among the health risks associated with low grip strength:

The prognostic merits of grip strength have been documented across continents and cultures. Although most of those studies have focused on older adults, they aren't the only age group researchers have looked at.

"We have several papers on the value of grip strength for predicting diabetes and cardiovascular disease in children and adolescents," Peterson says.

Survival of the Strongest

The first thing to understand about grip-strength testing is that it's only partially about grip. It's mostly about strength. That's what attracted Peterson to this line of research.

"I'm a former strength coach, so I wanted to make a case for why strength was important across populations, not just athletes," he says. "I strongly believe in strength preservation and healthy living as a predictor for longevity."

Consider a classic study of Swedish army recruits. Because of Sweden's post-World War II conscription policy, virtually every young male in the country underwent a physical examination to see if they were fit for military service — an exam that included a grip-strength test.

That gave the researchers a database with more than a million participants. They followed up on them decades later through publicly available records.

What they found: The men with the weakest grip strength in their late teens were 20% more likely to have died by their mid-50s, compared with those with moderate to high grip strength. Even suicide rates were 20%–30% higher for the weakest recruits.

There's a brutal Darwinian logic to the idea that a stronger person with a more powerful grip would enjoy a longer, healthier life. To our ancient ancestors, stronger hands meant you were probably better at everything that aided survival: hunting, fighting, building shelter, as well as bearing, transporting, and rearing children.

Fast forward to the 21st century where we must force ourselves to engage in physical activity. The old rules still apply: Strength aids survival.

Grip Strength and the Aging Process

Some of the earliest grip-strength studies used it as a proxy for nutritional status in elderly men and women. Nourishment, in turn, predicted their ability to survive an illness or surgery.

Which makes sense; if an older person isn't eating enough to maintain their health and vitality, their strength would decline. Declining strength would make them more susceptible to infections, hospitalizations, and post-surgical complications, leading to longer hospital stays, loss of independence, and ultimately a higher risk of death from any cause.

Along those lines, Peterson's research team at the University of Michigan found that low grip strength is correlated with faster aging at the cellular level.

The study looked at DNA methylation, which Peterson describes as "a reflection of someone's exposure to life events."

For example, someone who smokes will have altered methylation patterns compared with someone who doesn't. Same with someone who's had more exposure to environmental pollution.

Accelerated DNA methylation "means you're essentially at higher risk for what are traditionally considered age-related chronic conditions," Peterson says. Those conditions include Alzheimer's, type 2 diabetes, chronic inflammation, and a higher risk for premature mortality.

As you may recall, those things are also linked to low grip strength, which we now know is linked to higher DNA methylation and faster biological aging.

But there's still a missing piece of the puzzle: Why, exactly, would the strength of one's grip be associated with so many health outcomes?

Grip Strength and Muscle Function

"Declining muscle function is the first step of the disabling process," says Ryan McGrath, PhD, an assistant professor at North Dakota State University. "That's what you can measure with a handgrip test. It helps you identify individuals at risk for the next step of the process, which is declines in physical performance."

McGrath got involved in grip-strength research as a postdoctoral fellow at the University of Michigan, where he worked with Peterson. Like his mentor, he's published multiple studies using data obtained with a handgrip dynamometer.

"It can be a nice tool for assessing muscle function and muscle strength," he explains. Because the test is so easy to administer — you sit in a chair with your arm at your side and your elbow bent 90 degrees, and squeeze the device as hard as you can — researchers can work with large groups of study participants and come away with statistically powerful data.

"There are a lot of health outcomes it's associated with," McGrath adds, "which is one of its greatest strengths and at the same time one of its key limitations."

He compares the dynamometer to a tire gauge. Just as a tire gauge can alert you to a loss of air pressure without revealing the source of the leak, a dynamometer can't tell you why your grip strength is deflated.

"It's hard to specify the prognostic value," he says. "You don't know the next steps to take. As a stand-alone measurement, that's a concern."

That's why his current research goes beyond simple tests of maximum grip strength to more sophisticated measurements of the rate of force development (how fast you can express strength), repeatability (how much your strength declines from your first to your second or third squeeze) and asymmetry (how big a gap there is between your right- and left-hand strength).

Any of those measures could detect a potential neural or neuromuscular issue.

In a 2020 study, for example, McGrath and his team at NDSU showed that older adults with both weakness and asymmetry in grip-strength tests were nearly four times more likely to experience functional limitations. Those limitations could affect their ability to do anything from routine chores to keeping themselves clean and fed.

That brings us to perhaps the most important question:

Once you have grip-strength data on a patient, client, or yourself, what do you do with it?

Waging War on Weakness

Defining weakness is easy. Using dynamometer readings, the generally accepted cutoffs for low grip strength are 26 kg for an adult male and 16 kg for a female. (It's better to use kilograms instead of pounds, as you'll see in a moment.)

But that's way too simple, Peterson says.

For one thing, your age matters. Grip strength typically peaks for men in their late 20s and declines rapidly in middle age and beyond. For women, it plateaus in their 20s and gently declines until their 50s. So, at minimum, you should consult the age-based standards you'll find included with a dynamometer.

Another caveat: Peterson says grip strength tests aren't very meaningful for people who actively train for strength, though he suggests dedicated athletes make up a relatively small percentage of the population — even as low as 10%.

The size of the person taking the test is also important.

"You absolutely must account for body mass in the context of understanding how grip strength, or any strength measure, is reflective of health and function," Peterson says.

To calculate your strength-weight ratio, which Peterson calls "normalized grip strength," simply divide your grip strength in kilograms by your body weight in kilograms. For men, a ratio greater than 0.70 puts you in the higher percentiles. For women it's 0.50.  (You can find a complete chart of normalized grip strength percentiles here).

And if the results suggest that the person in question is objectively weak? "For me, that's easy," Peterson says. "They need to exercise."

Common sense suggests doing a lot of forearm exercises for grip strength. Not so, says Peterson. The strength of your hand and forearm muscles reflects what they can do along with all your other muscles moving together.

A 2019 study found that, for older adults, a variety of exercise programs can lead to modest but meaningful increases in participants' grip strength — and they don't necessarily have to include actual gripping exercises. The programs ranged from Tai Chi to water aerobics to walking, stretching, and all kinds of resistance training.

Peterson's advice to everyone is pretty straightforward: Get stronger. It doesn't really matter how you do it, or how much strength you ultimately gain. Even a little more strength means a little less weakness, and a little more life.

 

 



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