2019-06-01_New_Scientist (1)

illuminance. Research in mice may provide

insight into why this happens. When mice

were injured to simulate a heart attack, there

was a significant difference in the number and

type of immune cells that rallied to the heart,

and in the amount of scar tissue that formed,

depending on whether they recovered in a

cage with a disrupted light environment, as

you would find in many hospitals, or a more

natural 24-hour, light-dark cycle. Those with

disrupted rhythms were more likely to die

from their injury.

As for whether human-centric lighting can

help those who aren’t living in a care home or

recovering in hospital, there is some evidence

that it can improve healthy people’s sleep.

But Figueiro is less convinced by other claims,

for example that it boosts productivity. “In

many cases, human-centric lighting is being

oversold and overstated,” she says. “Usually,

people are only talking about spectrum when

it comes to circadian lighting. They are not

talking about the amount, timing or

distribution, and it is how much light that’s

getting into the eyes that matters.”

There is still much to learn about how

light – and darkness – affect our biology. “How

much light do we actually need, at what time

of day do we need what, and how often do we

need it? We just don’t know these things at the

moment,” says Wulff. Yet as a basic principle,

we should all be striving to brighten our days

and darken our nights. We evolved on a planet

with a 24-hour cycle of darkness and light.

It is time to reconnect with those extremes. ❚

You have probably heard that

being exposed to blue light in

the evening can disrupt your

circadian rhythms and imperil

your health. But how bright – and

how blue? Mariana Figueiro and

her colleagues of the Lighting

Research Center at Rensselaer

Polytechnic Institute in New

York state are testing this by

measuring melatonin, a hormone

linked to sleep that rises during

the evening in response to a

signal from your body clock.

Several studies have

suggested that the light from

smartphones can disrupt sleep,

but Figueiro’s team found that

only larger devices produce

enough bluish-white light to

affect levels of melatonin: for

adults, it was 85 lux for 1 hour’s

exposure, while for adolescents

it was 71 lux. “A larger iPad could

provide that amount of light,

or a little bit more, but phones

typically don’t,” says Figueiro.

However, they found that lower

light intensities could suppress

melatonin if people were

exposed to them for longer

periods of time.

For light sources emitting

a warmer colour, such as

incandescent light bulbs or

warm-white LEDs, the typical

levels found in a living room in

the evening wouldn’t suppress

melatonin production. Nor

would a TV screen watched

from 2 metres or more.

That may be key: how close

the light is to your eyes can make

a difference. In a separate study,

Figueiro discovered that even in

night-shift mode, which reduces

light from the blue part of the

spectrum, an iPad could suppress

melatonin. Her recommendation:

“Just turn it off.”

was left unchanged. After 3.5 years, residents

who were exposed to the brighter daytime

lighting showed less cognitive deterioration

and fewer symptoms of depression. When

bright light was combined with melatonin

supplements, they also slept better and

were less agitated.

Bright ideas

Others have tried to replicate these findings,

with mixed results. Figueiro suspects that

may be down to inconsistencies in the amount

of light actually being delivered into each

person’s eyes. “If people don’t take their

medication, you’re not going to see any effect,

but that doesn’t mean the medication doesn’t

work,” she says. “It is the same thing with

light.” To address this, she has been trialling

a “light table” that directs light upwards into

people’s eyes. A soon-to-be-published study

will show that this improves sleep, reduces

depression and decreases agitation in people

with dementia, she says.

Poor lighting is also a problem in many

hospitals, which tend to have dim lights left

on day and night. A 2017 study found that the

average daytime illuminance in a UK intensive

care unit was 159 lux. At night, it was 10.

People being cared for in such units often

have disrupted circadian rhythms, which

are associated with impaired recovery from

illness, says David Ray at the University of

Manchester, UK. Compounding the problem,

certain drugs, including morphine,

can further disrupt circadian clocks.

Hospital patients recover faster when

they have greater access to daylight. In one

study, the average length of stay for people

recovering from heart surgery was reduced by

7.3 hours for every 100 lux increase in daytime

Linda Geddes is a New Scientist

consultant and author of Chasing the

Sun: The new science of sunlight and

how it shapes our bodies and minds

JUST HOW BAD

IS BLUE LIGHT?

In the West

people spend

almost all their

time indoors,

in artificial light

38 | New Scientist |1 June 2019

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