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Transcript 
Birefringence
Bi
fi
imaging
i
i off
spermatozoa spindle
spermatozoa,
and zona pellucida
Markus Montag
Dept. Gynecological Endocrinology & Reproductive Medicine
University of Bonn, Germany
History of polarization microscopy
• 1808: Malus discovers „Polarization“
• 1815 / 1852: Brewster´s law / Strokes parameter
are basics for the application of polarization
• 1834: first commercial polarization microscope
• 1875:
1875 E
Engelmann
l
di
discovers bi
birefringence
fi
iin th
the
sperm from frog
• 1924: Schmidt describes cytoskeletal elements
publish various
• 1953-1981: Inoué & Allen p
ground breaking articles on microtubules and
spindle
Principle of polarization microscopy
• Shows
structures
with birefringent
properties
A l
Analyzer
Polarizer
Birefringence
g
imaging
g g in sperm
p
• First report on birefringence of the sperm tail
by Engelmann
Engelmann, 1875
• Negative birefringence of the sperm head
related to chromatin orientation (Schmidt
(Schmidt,
1924, 1937; Pattri 1932)
• Inoué
I
é was the
h fi
first to show
h
that
h polarization
l i i
microscopy can be used to identify
acrosome-reacted
d spermatozoa (1981)
(1981),
further refined by Baccetti, 2004
Sperm birefringence as a selection
criterion in ART
• Gianaroli et al., 2008 a/b:
• Use of acrosome
acrosome-reacted
reacted spermatozoa (identified
by polarization microscopy) raises implantation
and p
pregnancy
g
y rates for severe Oat and testicular
spermatozoa
• Boudjema
oudje a et a
al.,, 2009:
009
• Sperm birefringence is more likely to characterize
spermatozoa
p
with normal morphology
p
gy
• Crippa et al., 2009:
• Sperm birefringence does increase the likelihood
of DNA strand integrity (less DNA fragmentation)
Birefringence imaging in oocytes
Richards, Biol Bull 1917
Polarization microscopy for detecting spindle and zona birefringence in oocytes:
- Spindle imaging / Zona imaging -
Where is the spindle
p
• Spindle
p
at ICSI
– First report that spindle is not
always where it should be: Silva
et al., 1999
– Report that visualization of the
spindle
i dl position
iti has
h no benefit
b
fit
at all: Woodward et al., 2008
Where is the spindle
p
• Spindlep
/p
polar body-relation
y
• Rienzi et al. 2003
– Negative effect of fertilization if PB and
spindle are dislocated, but no effect on
embryo development
• Cooke et al
al., 2003
– Positive effect if PB and spindle are
not dislocated on embryo development
• Taylor et al., 2008
– Dislocated PB are the result of a too
h h pipetting
harsh
i tti mode
d d
during
i
hyaluronidase preparation
• Polar bodies do move: Scott,
Scott 2008
What if we cannot see the spindle
p
No. of publications on the prognostic value
Spindle visible
Spindle not visible
Fertilization
4x↑
2xØ
Embryo dev. day 3
5x↑
2xØ
Blastocyste rate
2x↑
Preg.-/Impl.-rate
g
p
1x↑
1xØ
More information needed: Petersen et al., 2009 RBMOnline
Wh iis th
When
the spindle
i dl visible
i ibl
Temperature
• Critical temperature:
33oC
• Culture medium
• Heated
H t d surfaces:
f
• Stereo microscope
• Injection microscope
• Incubator
pH of the medium
Course of the meiotic cell cycle
Spindle bridge
MI -> MII
75-90 min
MII
40-60 min
Cave: Different timing in oocytes from IVM / unstimulated cycles
Presence of the spindle and
f ili i
fertilization
rates
Fertilization rates
78.3%
78.4%
64.0%
1 Observation:
1.
with spindle
no spindle
no spindle
2 Observation:
2.
with
ith spindle
i dl
with
ith spindle
i dl
no spindle
P < 0.05
Summary
y spindle
p
imaging
g g
• Spindle-Imaging
– Localisation during ICSI
(Silva et al. 1999)
– Enucleation
(Liu et al
al. 2000)
– Spindle-/polar body relation
(Rienzi et al. 2003)
– Chromatin
Ch
ti aberration
b
ti
(Wang et al. 2003)
• Spindle dynamics
– Temperature sensitivity
(Wang et al. 2001)
– Meiotic cell cycle
y
(Montag et al. 2006)
Spindle imaging – conclusions
• The benefit of spindle imaging is:
– To get better insight into the
meiotic time course
– To determine oocyte maturity
– To allow for better timing of ICSI
– To avoid oocytes with 3PN after ICSI
Spindle imaging during
cryopreservation
•
Slow freezing:
– Rienzi et al. 2004 / human:
• 37% oocytes with spindles present after thawing, but disappear later
• 57% of oocytes show a spindle after 3h incubation
– Bianchi et al. 2005 / human:
• spindle appears in 3-5h after thawing
– Coticchio et al. 2006 / human:
• Confocal microscopy shows aberrant spindles
– Sereni et al., 2009 / human:
• Spindle reformation in >80% with optimised protocols
•
Vitrification:
– Chen et al., 2004 / mouse:
• Spindles present in 50% of oocytes after warming
– Larman et al., 2007 / human + mouse:
• Spindles are constantly present
The multilaminar structure of the
human zona pellucida
zona layer
Zona-imaging
g g–ap
possible parameter
p
for cytoplasmic maturity?
Zonaimage – Cytoplasmic Maturity
Zona = product of the oocyte
Optimal
p
maturation = g
good structured zona
Results of zona-imaging
zona imaging
%
70,0
20
50
65
68 cycles
60,0
50,0
40 0
40,0
30,0
*
20 0
20,0
10,0
#
0,0
HZB/HZB
HZB/LZB
LZB/LZB
Kontrolle
LZB/LZB versus HZB/LZB and HZB/HZB
* P < 0.005 Pregnancy rate
# P < 0.025 Implantation rate
Embryo development on day 3
LZB
30
26,8
25
20
21,5
15
HZB
10
6
5
6,8
3,6
3,9
0
E b
Embryoscore
Bl t
Blastomere
Day 3: Embryoscore
No of blastomeres
No.
Embryo quality
Q lität
Qualität
P < 0.025
P = 0.089
0 089
P < 0.001
Number > 8-cell grade A on day 3
%
50
41,7
40
30
20
24,4
10
0
LZB
HZB
P < 0.025
0 025
Ebner et al.: Zona-Imaging correlates with blastocyst formation
F tilit & St
Fertility
Sterility
ilit 2010
Correlation Zona
Zona-Image
Image and ART
• Shen et al., 2005
• Raju et al., 2007
Retrospective
Retrospective
• Montag et al., 2007/8
Prospective
• Ebner et al., 2009
• Madaschi et al.,, 2009
Prospective
Prospective
p
• Cheng et al., 2010
Retrospective
Preg.-rate
Embyo development
Blastocyste formation
Impl./Preg.-rate
Embryo development
Blastocyste formation
Impl./Preg.-rate
p
g
Abortion rate
No clear effect in IVF
The zona pellucida as a marker for
oocyte quality?
• The zona pellucida is formed by the oocyte
during follicular growth
• An optimal follicular environment supports
th fformation
the
ti off a well-ordered
ll d d and
d
structured zona
• A good zona is an indirect characteristic for
an oocyte
y with a g
good follicular development
p
Gene expression in cumulus cells as
indicator of oocyte competence
Cumulus and granulosa cells:
regulate oocyte growth and
acquisition
q
of oocyte
y
developmental competence
Oocyte secreted factors:
direct differentiation and function
of cumulus cells
Bidirectional communication
via transzonal projections with
formation of gap junctions
Oocyte – cumulus cell regulatory
loop
From: Gilchrist et al., HRU 14, 2008
Expression
p
of candidate genes
g
in
cumulus cells relative to the zona score
• BMP15 (Bone morphogenetic protein 15)
- oocyte secreted
- central regulator of cumulus/
granulosa cell differentiation
• CX43 (Connexin 43)
- major protein of gap junctions
- formation of transzonal projections
• STAR (Steroidogenic Acute Regulatory Protein)
- critical in steroidogenic activity
- expressed in cumulus cells after LH
LH-surge
surge
• RPL-19 (Ribosomal protein L19)
- housekeeping
p gg
gene / - reference g
gene
Differences in g
gene expression
p
in
oocytes with a good zona score
Pregnancy
No pregnancy
Seven genes are differentially
expressed in cumulus cells
Assidi, Montag, van der Ven, Sirard, JARG, 2011 in press
Oocytes with high versus low
zona score
mRNA expression in peripheral cumulus cells
12
10
8
Low Score
6
High Score
4
2
0
BMP-15
CX-43
STAR
Values indicated as Means / Statistical comparisons done by ANOVA
Oocytes with high versus low
zona score
mRNA expression in corona radiata cells
12
N.S.
10
8
6
Low Score
P=0.031
High
g Score
4
2
NS
N.S.
0
BMP-15
CX-43
STAR
Values indicated as Means / Statistical comparisons done by ANOVA
Conclusions
• Polarization microscopy
py is a g
good
tool to judge the quality of lab
parameters ((temperature
p
p
/p
pH))
• Spindle- and Zona-imaging are
prognostic criteria in an ART cycle
(oocyte maturity / embryo-potential)
• No substitute for aneuploidy testing
• Basic research to fully understand
th underlying
the
d l i mechanisms
h i
iis still
till
needed
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