What happens to the human body in deep space? / Photo: © NASA/AFP/File
RBGPF
1.6000
The Fort Worth Press - What happens to the human body in deep space?
USD
-
AED 3.6725
AFN 63.503502
ALL 81.990336
AMD 370.903715
ANG 1.789884
AOA 918.000197
ARS 1401.993023
AUD 1.39913
AWG 1.8025
AZN 1.696504
BAM 1.67146
BBD 2.014355
BDT 122.739548
BGN 1.668102
BHD 0.377403
BIF 2975
BMD 1
BND 1.275858
BOB 6.936925
BRL 4.965705
BSD 1.000128
BTN 95.070143
BWP 13.576443
BYN 2.828953
BYR 19600
BZD 2.011854
CAD 1.36214
CDF 2315.999417
CHF 0.784106
CLF 0.023178
CLP 912.21986
CNY 6.83025
CNH 6.83533
COP 3728.45
CRC 454.739685
CUC 1
CUP 26.5
CVE 94.650328
CZK 20.87905
DJF 177.720468
DKK 6.39432
DOP 59.600085
DZD 132.411933
EGP 53.530803
ERN 15
ETB 157.075029
EUR 0.8557
FJD 2.202202
FKP 0.736222
GBP 0.739275
GEL 2.685011
GGP 0.736222
GHS 11.195005
GIP 0.736222
GMD 73.49532
GNF 8777.497369
GTQ 7.643867
GYD 209.252937
HKD 7.83558
HNL 26.629448
HRK 6.447202
HTG 130.892468
HUF 312.100503
IDR 17433
ILS 2.95367
IMP 0.736222
INR 95.350202
IQD 1310
IRR 1314999.999816
ISK 122.709857
JEP 0.736222
JMD 157.565709
JOD 0.709029
JPY 157.276498
KES 129.191543
KGS 87.420503
KHR 4011.999844
KMF 420.502192
KPW 899.999998
KRW 1475.990178
KWD 0.30811
KYD 0.833593
KZT 463.980036
LAK 21962.493505
LBP 89401.229103
LKR 319.60688
LRD 183.624998
LSL 16.83005
LTL 2.95274
LVL 0.60489
LYD 6.334982
MAD 9.246963
MDL 17.22053
MGA 4154.999745
MKD 52.771476
MMK 2099.74975
MNT 3576.675528
MOP 8.070745
MRU 39.949922
MUR 46.950046
MVR 15.454942
MWK 1741.501824
MXN 17.509742
MYR 3.964503
MZN 63.909913
NAD 16.830069
NGN 1370.929942
NIO 36.719711
NOK 9.27435
NPR 152.110449
NZD 1.702285
OMR 0.384497
PAB 1.000329
PEN 3.505986
PGK 4.332503
PHP 61.7085
PKR 278.749656
PLN 3.64193
PYG 6218.192229
QAR 3.642973
RON 4.441799
RSD 100.477983
RUB 75.00169
RWF 1460.5
SAR 3.752195
SBD 8.025868
SCR 13.35873
SDG 600.507781
SEK 9.299335
SGD 1.277245
SHP 0.746601
SLE 24.649962
SLL 20969.496166
SOS 571.499363
SRD 37.455993
STD 20697.981008
STN 21.15
SVC 8.752948
SYP 110.524984
SZL 16.82975
THB 32.770189
TJS 9.363182
TMT 3.505
TND 2.885502
TOP 2.40776
TRY 45.21975
TTD 6.794204
TWD 31.6445
TZS 2609.999854
UAH 44.075497
UGX 3753.577989
UYU 40.286638
UZS 11997.999952
VES 488.94275
VND 26323
VUV 118.778782
WST 2.715188
XAF 560.591908
XAG 0.013699
XAU 0.00022
XCD 2.70255
XCG 1.8029
XDR 0.69563
XOF 558.501381
XPF 102.375041
YER 238.625019
ZAR 16.80115
ZMK 9001.200271
ZMW 18.731492
ZWL 321.999592
- Asian stocks drop amid fears over US-Iran ceasefire
- China fireworks factory explosion kills 26, injures 61
- China hails 'our era' as Wu Yize's world snooker triumph goes viral
- Ex-model accuses French scout of grooming her for Epstein
- Timberwolves eclipse Spurs as Knicks rout Sixers
- Taiwan leader says island has 'right to engage with the world'
- Yoko says oh no to 'John Lemon' beer
- Bayern's Kompany promises repeat fireworks in PSG Champions League semi
- A coaching great? Luis Enrique has PSG on brink of another Champions League final
- Top five moments from the Met Gala
What happens to the human body in deep space?
Bone and muscle deterioration, radiation exposure, vision impairment -- these are just a few of the challenges space travelers face on long-duration missions, even before considering the psychological toll of isolation.
As US astronauts Butch Wilmore and Suni Williams prepare to return home after nine months aboard the International Space Station (ISS), some of the health risks they've faced are well-documented and managed, while others remain a mystery.
These dangers will only grow as humanity pushes deeper into the solar system, including to Mars, demanding innovative solutions to safeguard the future of space exploration.
- Exercise key -
Despite the attention their mission has received, Wilmore and Williams' nine-month stay is "par for the course," said Rihana Bokhari, an assistant professor at the Center for Space Medicine at Baylor College.
ISS missions typically last six months, but some astronauts stay up to a year, and researchers are confident in their ability to maintain astronaut health for that duration.
Most people know that lifting weights builds muscle and strengthens bones, but even basic movement on Earth resists gravity, an element missing in orbit.
To counteract this, astronauts use three exercise machines on the ISS, including a 2009-installed resistance device that simulates free weights using vacuum tubes and flywheel cables.
A two-hour daily workout keeps them in shape. "The best results that we have to show that we're being very effective is that we don't really have a fracture problem in astronauts when they return to the ground," though bone loss is still detectable on scans, Bokhari told AFP.
Balance disruption is another issue, added Emmanuel Urquieta, vice chair of Aerospace Medicine at the University of Central Florida.
"This happens to every single astronaut, even those who go into space just for a few days," he told AFP, as they work to rebuild trust in their inner ear.
Astronauts must retrain their bodies during NASA's 45-day post-mission rehabilitation program.
Another challenge is "fluid shift" -- the redistribution of bodily fluids toward the head in microgravity. This can increase calcium levels in urine, raising the risk of kidney stones.
Fluid shifts might also contribute to increased intracranial pressure, altering the shape of the eyeball and causing spaceflight-associated neuro-ocular syndrome (SANS), causing mild-to-moderate vision impairment. Another theory suggests raised carbon dioxide levels are the cause.
But in at least one case, the effects have been beneficial. "I had a pretty severe case of SANS," NASA astronaut Jessica Meir said before the latest launch.
"When I launched, I wore glasses and contacts, but due to globe flattening, I now have 20/15 vision -- most expensive corrective surgery possible. Thank you, taxpayers."
- Managing radiation -
Radiation levels aboard the ISS are higher than on the ground, as it passes through through the Van Allen radiation belt, but Earth's magnetic field still provides significant protection.
The shielding is crucial, as NASA aims to limit astronauts' increased lifetime cancer risk to within three percent.
However, missions to the Moon and Mars will give astronauts far greater exposure, explained astrophysicist Siegfried Eggl.
Future space probes could provide some warning time for high-radiation events, such coronal mass ejections -- plasma clouds from the Sun -- but cosmic radiation remains unpredictable.
"Shielding is best done with heavy materials like lead or water, but you need vast quantities of it," said Eggl, of University of Illinois Urbana-Champaign.
Artificial gravity, created by rotating spacecraft frames, could help astronauts stay functional upon arrival after a nine-month journey to Mars.
Alternatively, a spacecraft could use powerful acceleration and deceleration that matches the force of Earth's gravity.
That approach would be speedier -- reducing radiation exposure risks -- but requires nuclear propulsion technologies that don't yet exist.
Preventing infighting among teams will be critical, said Joseph Keebler, a psychologist at Embry-Riddle Aeronautical University.
"Imagine being stuck in a van with anybody for three years: these vessels aren't that big, there's no privacy, there's no backyard to go to," he said.
"I really commend astronauts that commit to this. It's an unfathomable job."
T.M.Dan--TFWP
