Since the Moon is now generally considered to be free from life, the most likely source of contamination would be from Mars during either a
Mars sample-return mission or as a result of a
crewed mission to Mars. The possibility of new human pathogens, or environmental disruption due to back contamination, is considered to be of extremely low probability but cannot yet be ruled out. NASA and ESA are actively developing a
Mars Sample Return Program to return samples collected by the Perseverance Rover to Earth. The European Space Foundation report cites many advantages of a Mars sample-return. In particular, it would permit extensive analyses on Earth, without the size and weight constraints for instruments sent to Mars on rovers. These analyses could also be carried out without the communication delays for experiments carried out by Martian rovers. It would also make it possible to repeat experiments in multiple laboratories with different instruments to confirm key results.
Carl Sagan was first to publicise back contamination issues that might follow from a Mars sample-return. In
Cosmic Connection (1973) he wrote: Later in
Cosmos (1980) Carl Sagan wrote: NASA and ESA views are similar. The findings were that with present-day technology, Martian samples can be safely returned to Earth provided the right precautions are taken.
Suggested precautions for sample-returns NASA has already had experience with returning samples thought to represent a low back contamination risk when samples were returned for the first time by
Apollo 11. At the time, it was thought that there was a low probability of life on the Moon, so the requirements were not very stringent. The precautions taken then were inadequate by current standards, however. The regulations used then have been rescinded, and new regulations and approaches for a sample-return would be needed.
Chain of contact A sample-return mission would be designed to break the chain of contact between Mars and the exterior of the sample container, for instance, by sealing the returned container inside another larger container in the vacuum of space before it returns to Earth.
Receiving facility To receive, analyze and curate extraterrestrial soil samples, NASA has proposed to build a biohazard containment facility, tentatively known as the Mars Sample Return Receiving Facility (MSRRF). This future facility must be rated
biohazard level 4 (
BSL-4). The facility's systems must be able to contain unknown biohazards, as the sizes of any putative Martian microorganisms are unknown. In consideration of this, additional requirements were proposed. Ideally it should filter particles of 0.01 μm or larger, and release of a particle 0.05 μm or larger is unacceptable under any circumstance. The reason for this extremely small size limit of 0.01 μm is for consideration of
gene transfer agents (GTAs) which are virus-like particles that are produced by some microorganisms that package random segments of
DNA capable of
horizontal gene transfer. Another reason for the 0.05 μm limit is because of the discovery of
ultramicrobacteria as small as 0.2 μm across. The facility would be expected to take 7 to 10 years from design to completion, and an additional two years recommended for the staff to become accustomed to the facilities.
Legal process of approval for Mars sample-return Margaret Race has examined in detail the legal process of approval for a MSR. Their reasoning is that life on Mars is likely to be hard to find. Any present day life is likely to be sparse and occur in only a few niche habitats. Past life is likely to be degraded by cosmic radiation over geological time periods if exposed in the top few meters of the Mars surface. Also, only certain special deposits of salts or clays on Mars would have the capability to preserve organics for billions of years. So, they argue, there is a high risk that a Mars sample-return at our current stage of understanding would return samples that are no more conclusive about the origins of life on Mars or present day life than the Martian meteorite samples we already have. Another consideration is the difficulty of keeping the sample completely free from Earth life contamination during the return journey and during handling procedures on Earth. This might make it hard to show conclusively that any biosignatures detected does not result from contamination of the samples. Instead they advocate sending more sensitive instruments on Mars surface rovers. These could examine many different rocks and soil types, and search for biosignatures on the surface and so examine a wide range of materials which could not all be returned to Earth with current technology at reasonable cost. A sample-return to Earth would then be considered at a later stage, once we have a reasonably thorough understanding of conditions on Mars, and possibly have already detected life there, either current or past life, through biosignatures and other
in situ analyses.
Instruments under development for in situ analyses • NASA Marshall Space Flight Center is leading a research effort to develop a Miniaturized Variable Pressure Scanning Electron Microscope (MVP-SEM) for future lunar and Martian missions. • Several teams, including Jonathan Rothberg, and J. Craig Venter, are separately developing solutions for sequencing alien DNA directly on the Martian surface itself. • Levin is working on updated versions of the Labeled Release instrument flown on Viking. For instance versions that rely on detecting chirality. This is of special interest because it can enable detection of life even if it is not based on standard life chemistry. • The Urey Mars Organic and Oxidant Detector instrument for detection of biosignatures has been descoped, but was due to be flown on
ExoMars in 2018. It is designed with much higher levels of sensitivity for biosignatures than any previous instruments.
Study and analyses from orbit During the “Exploration Telerobotics Symposium" in 2012, experts on telerobotics from industry, NASA, and academics met to discuss telerobotics and its applications to space exploration. Amongst other issues, particular attention was given to Mars missions and a Mars sample-return. They came to the conclusion that telerobotic approaches could permit direct study of the samples on the Mars surface via telepresence from Mars orbit, permitting rapid exploration and use of human cognition to take advantage of chance discoveries and feedback from the results obtained. They found that telepresence exploration of Mars has many advantages. The astronauts have near real-time control of the robots, and can respond immediately to discoveries. It also prevents contamination both ways and has mobility benefits as well. Finally, return of the sample to orbit has the advantage that it permits analysis of the sample without delay, to detect volatiles that may be lost during a voyage home. Similar methods could be used to directly explore other biologically sensitive moons such as
Europa,
Titan, or
Enceladus, once human presence in the vicinity becomes possible. ==Forward contamination==