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Advanced Topics in Space Studies: Commercial Barriers and Solutions

Advanced Topics in Space Studies: Commercial Barriers and Solutions. Human Factors/Space Medicine Dr. John M. Jurist Biophysicist CRM, Inc. What Happens to People Living and Working in Space?. The dream:. What Happens to People Living and Working in Space?. Reality:. Human Factors.

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Advanced Topics in Space Studies: Commercial Barriers and Solutions

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  1. Advanced Topics in Space Studies: Commercial Barriers and Solutions Human Factors/Space Medicine Dr. John M. Jurist Biophysicist CRM, Inc.

  2. What Happens to People Living and Working in Space? The dream:

  3. What Happens to People Living and Working in Space? Reality:

  4. Human Factors Space is a very, very hostile and unforgiving place: • None of the comforts of home unless brought along • It is largely empty (both blessing and curse) • Transport from Earth is very expensive • We don’t really know much about living there • Repairs and help are far away • Truism: Space can always hurt you more

  5. 862 gms O2 2,200 gms H2O 523 gms food 982 gms CO2 2,542 gms H2O 61 gms solid waste (min) Human Factors Consumables for a 70 kg Man (level flying) at 2,830 kcal/day on specific diet: (after Hans G. Clamann, Problems of Metabolism in Sealed Cabins)

  6. Air Water/urine Food/solid wastes Toxic accumulations of whatever Human Factors Consumables requirements make recycling more attractive for longer missions and larger crews:

  7. Human Factors Considered in the context of mission parameters: • Suborbital • Orbital • Lunar • Solar System

  8. Human Factors Considered in the context of mission parameters: • Duration • Life Support • Consumables • Acceleration • Microgravity • Radiation • Other Considerations

  9. Human Factors Suborbital: • Duration – minutes • Life support – hypoxia – pressure suits • Consumables – minimal – no waste handling • Acceleration – multidirectional? – cardiac arrhythmias • Microgravity – nausea (in a pressure suit?) • Radiation – negligible

  10. Human Factors Orbital: • Duration – hours to weeks • Life support – + contaminants, noise • Consumables – +transported and stored • Acceleration – + tolerance after microgravity • Microgravity – +fluid shift, bone & muscle atrophy • Radiation – not negligible • Other – medical emergencies – can’t call 911

  11. Human Factors Lunar: • Duration – hours to weeks • Life support – + contaminants, noise • Consumables – +transported and stored • Acceleration – + tolerance after microgravity • Microgravity – +fluid shift, bone & muscle atrophy • Radiation – roughly 2x orbital, flares fatal • Other – dust, medical emergencies, procreation?

  12. Pulmonary Physiology Abating effects of altitude: • Pressurize the cabin – 8,000 feet airline standard • Supplemental oxygen

  13. Pulmonary Physiology Pressurizing cabin to 8,000 feet results in inadequate oxygen saturation and need for additional oxygen for otherwise healthy people: • 44% of 65 year old • 27% of 55 year old • 14% of 45 year old

  14. Pulmonary Physiology Breathing pure oxygen at altitude equivalent to: • Sea level air at 33,000 feet • 10,000 feet air at 39,000 feet • 20,000 feet air at 45,000 feet

  15. Pulmonary Physiology Pressure suits: • Full pressure suit more than $1 Million • EVA capable suit more than $3 Million • Partial pressure suits uncomfortable -- Get me down alive !! • Poor heat dissipation especially with exercise • Heat stroke running from downed spacecraft?

  16. Acceleration Effects Acceleration duration: • Prolonged if more than 0.2 seconds • Fluid shifts important and dominate effects • Impact if less than 0.2 seconds • Viscoelastic nature of tissues • Delta-V or acceleration onset best indicator

  17. Acceleration Effects Acceleration definitions: • Eyeballs down plus Gz • Eyeballs up minus Gz • Eyeballs in plus Gx • Eyeballs out minus Gx

  18. Acceleration Effects Prolonged acceleration: • Normal blood pressure at heart 120/75 mm Hg • Pulmonary artery 20/7 mm Hg • Pressure drop to brain 35 mm Hg at 1 G • Pressure drop to brain of 105 mm Hg at 3 G • Venous blood pooling

  19. Acceleration Effects Prolonged acceleration: • Grey out, loss of vision, loss of consciousness • Visual acuity decrease (deformation) • Compensatory mechanisms • Carotid sinus reflex dominates (5 seconds) • Respiratory difficulties

  20. Acceleration Effects Abating effects of prolonged acceleration: • Decrease uphill heart-brain distance • Modify flight profile • Counter pressure suit to decrease blood pooling • Counter pressure by straining

  21. Acceleration Effects Cardiac effects of prolonged acceleration: • Irregular heart beat 47% medical professionals • 4.5% potentially dangerous • Irregular heart beat 30-50% fighter pilots • 4.6% potentially dangerous • Aging effects poorly characterized

  22. Consideration of Failure • Fundamental decisions: • Vertical or horizontal takeoff and landing • FAA/AST-2 essentially laissez faire • Definition of failure modes and probabilities • Passenger education and training

  23. Consideration of Failure • Ejection seat utility: • Part of atmospheric flight • HTO vehicle in early flight • Limited at high speeds • Limited at high stagnation temperatures

  24. Consideration of Failure • Ejection seat upper envelope: • Mach 0.9 at sea level • Mach 3.7 at 65,000 feet • High stagnation temperatures above 65,000 feet

  25. Consideration of Suborbital Failure • Cabin depressurization: • Unstrap for short time in microgravity? • Emergency egress for landing mishaps • Lawyers have 20-20 hindsight • So do congressional committees

  26. Radiation Exposure • Sources of exposure: • On board fluid level sensors • Cosmic photons (includes gamma bursts) • Cosmic particulate radiation • Solar photons • Solar particulate radiation (includes flares) • Trapped particulate radiation belts (Van Allen) • Terrestrial background

  27. Radiation Exposure • Units: • Energy/Mass Bioeffect • 100 Rad times Q(RBE) 100 Rem • 1 Gray (Gy) times Q 1 Sievert (Sv)

  28. Radiation Exposure • Short term acute whole body exposure (rems): • 10-50 Minor blood changes • 50-100 5-10% nausea (1 day), blood, survivable • 100-200 1/4-1/2 nausea (1 day), blood, GI, survivable • 200-350 Most nausea (1 day), blood, GI, 5-50% die • 350-550 450 LD50 Most nausea, blood, GI, 50-90% die • 550-750 Nausea (hours), blood, GI, almost all die • 750-1,000 Nausea (hours), blood, GI, fatal (2-4 weeks) • 1,000-2,000 Nausea (hours), fatal (2 weeks) • 4,500 Incapacitation (hrs), fatal (1 week)

  29. Radiation Exposure • Living and medical: • Polar airline flight 0.10-0.23 mSv per day • 2 view chest X-ray 0.06-0.25 mSv • Bone scan 0.15 mSv • Chest CT 0.3-30 mSv (typical 10 mSv) • Billings MT background 1.2 mSv per year (quiet sun) • Typical US background 2.4 mSv per year • Typical US medical 0.6 mSv per year

  30. Radiation Exposure

  31. Radiation Exposure • Based on HTO suborbital: • Upper limit 0.0053 mSv per flight • Polar airline flight 0.10-0.23 mSv per day

  32. Radiation Exposure • Based on orbital and beyond: • 0.6-0.9 mGy/day (Skylab) • 0.2-1.3 mGy/day (Apollo landing flights) • ~0.06 mGy/day (STS) • 0.049-1.642 mGy/day (STS-2, STS-31) • 0.053 mGy/day 0.146 mSv/day galactic cosmic • 0.042 mGy/day 0.077 mSv/day trapped belt

  33. Radiation Exposure • The problem: • 2 view chest X-ray 0.06-0.25 mSv • Public limit 1 mSv per year • NASA classifies astronauts as radiation workers • Worker whole body 50 mSv or 0.05 Sv per year • Worker organ limit 0.5 Sv per vear • Worker organ limit 0.25 Sv per month

  34. Radiation Exposure • Career limits for radiation workers (1994): • Blood-Forming Organs • Limit at Lens Skin Male Female • Age 25 4.0 Sv 6.0 Sv 1.5 Sv 1.0 Sv • Age 35 4.0 Sv 6.0 Sv 2.5 Sv 1.75 Sv • Age 45 4.0 Sv 6.0 Sv 3.2 Sv 2.5 Sv • Age 55 4.0 Sv 6.0 Sv 4.0 Sv 3.0 Sv

  35. Radiation Exposure • Radiation carcinogenesis: • 0.5/106/mSv/year Breast • 0.4/106/mSv/year Thyroid • 0.3/106/mSv/year Lung • 7-17/106/mSv/year All cancers • 100 mSv/105 800 deaths added to 20,000 w/o radiation (4% increment/10 rads) • 10 mSv/year cont. 5% increment/1 rad lifetime increase

  36. RadiationExposure Is radiation a show-stopper for a trip to Mars? • Minimum energy transfer roughly 9 months each way • Assume STS-like free space galactic radiation exposure of 0.146 mSv/day • 270 days times 0.146 mSv/day = 39.4 mSv for 1 way • Is it legal? 50 mSv/year whole body worker limit • Is it legal? Compare to career limits (3 Sv age 55) • Boost cancer death risk 1.7% for baseline trip to Mars • Boost cancer death risk 25% for continuous 0.146 mSv/day • Flares and Mars orbit time, surface time • Radiation issues become significant

  37. Radiation Exposure • The conundrums: • Are long term space missions legal? • Informed consent vs. legal limitations • Conceive and raise children? • Remember planets shield by geometry • Large variability in exposure (flares) • Large variability in response

  38. Weightlessness • Based on HTO suborbital: • Maximum of 3½ minutes of microgravity • Greatest risk is nausea (other risks in orbit) • Familiarization aircraft flights • Minimize head movements • Medication • Avoid vomiting into oxygen mask or closed helmet • Nausea is contagious (smells and sounds)

  39. Discussion

  40. Suborbital Human Factors Status Alt.space awaremess is dismal: • Assumption that it is accomplished and can be ignored • Lack of appreciation of risks • Aging normative population undefined • Suborbital floating free in shirt sleeves? • Buy a Russian space suit on EBAY

  41. Orbital (and Beyond) Human Factors Status Alt.space awaremess is even more dismal: • Assumption that it is accomplished and can be ignored • Lack of appreciation of risks • Aging normative population undefined • Minimal gravity level is undefined • Radiation issues become significant • Working is microgravity is hard

  42. Orbital (and Beyond) Human Factors Status Why? Culture shock (engineering vs. biomedical): Engineers look for limiting parameters Engineers design to limiting parameters Engineers minimize variables Human responses vary enormously Human responses probabilistic Human responses – many variables Human responses poorly characterized Never say never in medicine

  43. Orbital (and Beyond) Human Factors Status Medical issues related to living in space and going to Mars: • Outside assistance is impossible or very difficult • Life support degradation – toxin accumulation • Acute urinary retention -- renal lithiasis • Cardiac event • Cancer (Antarctica example) • Drug shelf life (accelerated degradation with radiation) • Medical/surgical infrastructure -- how much is enough?

  44. Opportunities What we don’t know can hurt us or provide opportunities for play/research: • Microgravity – musculoskeletal, cardiovascular, reproductive, and immune systems; embryogenesis, fetal development; aging; optimization • Radiation – shielding (mass, electrostatic, or magnetic), abatement (pharmaceutical, antioxidants, modification of humans – genetic engineering) • Long term exposure to different gas mixes vs. standard air • Other – lunar dust and urban/rural pollution effects

  45. Opportunities Role for small business niche operations: • Training MDs in aerospace medicine • Training passenger candidates • Screening passenger candidates • “Space Camp” for passengers • Life support equipment – esp. pressure suits • Ever present consulting

  46. Opportunities Role for academic operations: • Training MDs in aerospace medicine • Training passenger candidates • Education – public outreach • Research – specialized – intradepartmental • Research – interdisciplinary – multidepartmental or multischool • Ever present consulting

  47. Solutions Becoming a spacefaring culture: • Drive down cost to LEO and beyond • Find and exploit commercial opportunities • Justification for manned presence • Technology (microgravity, radiation, life support) • Technology (shorten trip times) • Motivation (national security?, lifeboat?)

  48. Solutions Becoming a spacefaring culture: • Time • Money • Research • Technology • Management • Motivation

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