Sure. Considered.

Federal Standard 376-B, January 27, 1993; page 5
http://ts.nist.gov/ts/htdocs/200/202/fs376-b.pdf

"4.3.2 Deprecated Names or Symbols. Other units from older versions of
the
metric system and metric jargon that shall not be used include:
Incorrect term Correct Unit
kilo kilogram
are square dekameter
candle or
candlepower candela
fermi femtometer
gamma nanotesla
micron micrometer
millimicron nanometer
mho siemens
ã microgram
ë cubic millimeter or microliter

4.3.3 Miscellaneous Non-SI Units Not to be Used. Additional units
that are not accepted for use include the following:
angstrom
calorie
g as a unit of acceleration (g = 9.81 m/s2)
grade or gon [1 grade = (ƒÎ/200) rad]
kilogram-force
langley (1 langley = 1 cal/cm2)
metric carat
metric horsepower
millimeter of mercury
millimeter, centimeter, or meter of water
standard atmosphere (101.325 kPa)
technical atmosphere (98.0665 kPa)
torr (133.322 Pa)"
This is the old standard. The NIST states the history of the standard
and the new definition of the meter:

"2.1.1.1 Unit of length (meter) The 1889 definition of the meter,
based upon the international prototype of platinum-iridium, was
replaced by the 11th CGPM (1960) using a definition based upon a
wavelength of krypton 86 radiation. This definition was adopted in
order to improve the accuracy with which the meter may be realized.

This was replaced in 1983 by the 17th CGPM (Resolution 1; CR, 97 and
Metrologia, 1984, 20, 25):

The meter is the length of the path travelled by light in vacuum
during a time interval of 1/299 792 458 of a second.

Note that the effect of this definition is to fix the speed of light
at exactly 299 792 458 m/s. The original international prototype of
the meter, which was sanctioned by the 1st CGPM in 1889 (CR, 34-38),
is still kept at the BIPM under conditions specified in 1889."

See http://physics.nist.gov/Pubs/SP330/sp330.pdf, page 5.

Now, since the length of the meter is a function of time, we need a
proper definition of a second.

"2.1.1.3 Unit of time (second)
The unit of time, the second, was at one time considered to be the
fraction 1/86 400 of the mean solar day. The exact definition of "mean
solar day" was based on astronomical theories. However, measurement
showed that irregularities in the rotation of the Earth could not be
taken into account by the theory and have the effect that this
definition does not allow the required accuracy to be achieved. In
order to define the unit of time more precisely, the 11th CGPM (1960;
CR, 86) adopted a definition given by the International Astronomical
Union which was based on the tropical year. Experimental work,
however, had already shown that an atomic standard of time interval,
based on a transition between two energy levels of an atom or a
molecule, could be realized and reproduced much more precisely.
Considering that a very precise definition of the unit of time is
indispensable for the International System, the 13th CGPM
(1967-1968, Resolution 1; CR, 103 and Metrologia, 1968, 4, 43)
replaced the definition of the second with the following:

The second is the duration of 9 192 631 770 periods of the radiation
corresponding to the transition between the two hyperfine levels of
the ground state of the cesium 133 atom.

At its 1997 meeting, the CIPM affirmed that:

This definition refers to a cesium atom at rest at a
temperature of 0 K.

This note was intended to make it clear that the definition of the SI
second is based on a Cs atom unperturbed by black-body radiation, that
is, in an environment whose temperature is 0 K, and that the
frequencies of primary frequency standards should therefore be
corrected for the shift due to ambient radiation, as stated at the
meeting of the CCTF in 1999."

ibid. http://physics.nist.gov/Pubs/SP330/sp330.pdf, page 6.

Nope.

So you, in fact, do not have 12 fingers?