10 | New Scientist | 13 July 2019
News
Mathematics
TAKING sperm directly from the
testicles rather than using semen
may help some couples conceive
through IVF.
The approach has been used for
some time in men who are infertile
because they have a blockage in the
tubes that take sperm to the penis,
for example. It is now being offered
more widely, partly because of a
suspicion that some infertility may
be down to damage occurring to
sperm after they have formed,
through exposure to free radicals.
“Free radicals are very
detrimental to sperm DNA,” says
Sandro Esteves of Androfert, a male
infertility centre in Campinas, Brazil.
But sceptics are concerned that
by taking sperm from the testicles,
doctors may inadvertently select
less fit sperm, which could lead
to health problems for the baby.
Esteves and his colleagues
looked at data from 86 couples
with unexplained infertility and
sperm DNA damage who visited
the Androfert centre. Thirty-six had
IVF using sperm from their testicles.
The rest had IVF using sperm
from semen.
Regardless of the method used,
the team found that the eggs had
a similar chance of being fertilised
and developing into embryos with
the right number of chromosomes.
Esteves presented the results at
the European Society of Human
Reproduction and Embryology
conference in Vienna.
Kevin McEleny at the Newcastle
Fertility Centre, UK, would still like
to see evidence of improved live
birth rates before the technique is
used more widely. ❚
THE legendary mathematician
Srinivasa Ramanujan was
known for coming up with
unconventional mathematical
ideas. He has now inspired a
computer program that does
the same.
Called the Ramanujan Machine,
the software poses conjectures
for generating equations
whose output is fundamental
mathematical constants such as π
and e. A conjecture is an unproven
mathematical statement.
Born in 1887 in what is now
Tamil Nadu in India, Ramanujan
was a self-taught mathematician.
He often claimed that his
results came to him in a
dream, and disliked the formal
proofs favoured by most
mathematicians. Ramanujan
moved to the UK in 1914 to study
at the University of Cambridge
with the mathematician G. H.
Hardy, and their long friendship
led to a series of important results
in the field of number theory.
“Ramanujan had a way of
producing things which looked
true [but] he couldn’t necessarily
convince other people why they
were true,” says Saul Schleimer
at the University of Warwick, UK.
Many of Ramanujan’s conjectures
were later formally proven.
The theorems Ramanujan
produced often involved
continued fractions, which
express a number as the sum
of infinitely nested fractions.
To mimic this approach, Gal
Raayoni at the Israel Institute of
Technology and his colleagues
created the Ramanujan Machine.
It has already come up with tens
of conjectures that use continued
fractions to approximate π and e
(arxiv.org/abs/1907.00205).
One method the program uses
to search for new conjectures is a
“meet in the middle” approach.
This involves generating many
mathematical expressions,
computing their value for a
limited number of iterations
and eliminating the expressions
that give inaccurate results.
For example, when trying to
approximate e, whose value is a
decimal that begins 2.718..., any
potential conjectures that yield
numbers with a value that is too
high or too low are eliminated.
Conjectures that appear to work
are then calculated for more
iterations to identify ones likely
to be true. This approach gave the
new conjecture shown on the left.
Schleimer likens the method
to an extensive process of trial
and error. “What they’re doing
is a nice piece of experimental
mathematics,” he says. “But it’s not
like this is a new way of thinking.”
Some of the formulas the
Ramanujan Machine has come
up with are new, while others have
previously been discovered by
human mathematicians.
The team wants people to
submit suggested proofs to the
new conjectures, as it is impossible
to prove they are correct with
simple arithmetic since they
involve infinite sums.
“It produces conjectures
without exactly knowing why
they’re true and it likes continued
fractions, which Ramanujan was
very, very fond of, ” says Schleimer.
But it can’t really match him, he
says. “Ramanujan’s continued
fractions were more subtle and
in some sense more mature.”
The researchers behind the
Ramanujan Machine have also
shared its software, so anyone can
download the programme to run
on their own computer while it
isn’t in use. Any conjectures a
participant discovers will be
named after them, says the team. ❚
Infertility
Donna Lu
SC
IEN
CE
PH
OT
O^ L
IBR
AR
Y
Extracting sperm
from testicles may
help infertility
Clare Wilson
Computer attempts to replicate the
dream-like maths of Ramanujan
US
UM
U^ N
ISH
INA
GA
/SP
L
Sperm in the
testicles haven’t
been exposed
to as many free
radicals, which
damage DNA
e=^3 +
(^4) +
(^5) +
(^6) +
(^7) +...
— 1
— 2
— 3
— 4
Srinivasa Ramanujan, above,
came up with many equations
similar to the one below, but
this formula for the constant e
was created by a machine
“ Ramanujan had a way of
producing things which
looked true but he couldn’t
always convince others”