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Rectal proliferation and polyp occurrence in patients with familial adenomatous polyposis after sulindac treatment
GASTROENTEROLOGY 1994;106:362-366
Recta1 Proliferation and Polyp Occurrence in Patients With Familial Adenomatous Polyposis After Sulindac Treatment MARIA TERESA SPAGNESI,* FRANCESCO TONELLI,’ PIER0 DOLARA,* GIOVANNA ROSA VALANZANO,’ ALESSANDRO ANASTASI,’ and FRANCA BIANCHINI* *Department of Pharmacology and Toxicology and ‘Surgical Unit, Department of Clinical Physiopathology, Florence Italy
Sulindac, a nonsteroidal anti-inflammatory drug (NSAID), decreases the occurrence of polyps in patients with familial adenomatous polyposis (FAP). The effects of colectomy with ileorectal anastomosis (IRA) and sulindac treatment on recta1 mucosa proliferation and polyp occurrence were examined in patients with FAP. Methods: The number and size of recta1 polyps were measured with colonoscopy. The labeling index, the percentage of labeled cells per crypt compartment, was assessed in recta1 biopsy specimens with [3H]thymidine incorporation and autoradiography in 6 non-IRA and 14 IRA patients before and after treatment with 200 mg of sulindac/day for 60 days. Results: The IRA patients had a lower labeling index and a decrease in the percentage of labeled cells in the upper compatiment of the crypt (P < 0.01) relative to non-IRA sub jects. Sulindac did not influence the labeling index and the distribution of labeled cells along the crypt. On the contrary, a dramatic decrease in the size and number of polyps was observed after sulindac treatment (P < 0.001). Conclusions: The persistente of a abnormal mucosal proliferation after sulindac therapy, in spite of the reduction of polyp number, suggests caution in assuming a lower risk of recta1 cancer in patients with FAP. Bac/@ound/Aims:
F
amilial adenomatous polyposis (FAP), if left unattended, inevitably progresses to colorectal cancer. The current surgical treatments of this condition are total colectomy with ileoanal pul1 or ileorectal anastomosis (IRA). The latter
is a simpler
technique
and guarantees
satisfactory functional results in properly selected subjects. However, after IRA, patients with FAP must undergo lifelong surveillance of the recta1 stump for the early detection of new polyps and cancer.‘.’ It has been reported that after IRA, one third of patients with FAP have a complete spontaneous regression of recta1 polyps and lower frequenties of neoplastic transformation when compared with patients affected by the same disease who did not undergo 1RA.s However, surgical treatment with IRA does not annul the risk of colon cancer.” In fact, patients with FAP are characterized by a state of hyperproliferation in the colonic mucosa and by a shift of the proliferative zone to the upper portion
of the colonic
CADERNI,”
University of Florence,
crypts,5.” factors wel1 correlated
risk of cancer development.‘-”
We previously
with the showed
that after IRA, the proliferative pattern of the recta1 stump regresses to normality, but some indicators of an abnormal putrescine a 13%
control
of cel1 division,
and spermine, incidence
reported
for patients
of colon
subjects,2
cancer
after IRA
has been
with FAP in the 25 years following
surgery. ‘JI This frequency non-IRA
such as the polyamines
remain elevated.‘> Accordingly,
is lower than that recorded
but the individual
in
risk of developing
cancer is far from negligible. A few years ago it was reported that some nonsteroidal anti-inflammatory drugs (NSAIDs) were able to control the growth of desmoid tumors in patients affected by FAP or Gardner’s syndrome.‘“-‘” It was later shown that sulindac(ris-5-fluoro-2-methyl-l-~p-(methylsulfynil)benzylidenel
indene-3-acetic
acid), a widely
can also cause polyp regression.‘0-2i ies in patients 6-12 months sulindac
used NSAID,
In one of these stud-
with FAP, al1 polyps disappeared during of therapy with a dose of 300-400 mg
per day.2’ In other recent
studies,
a reduction
of the number and size of adenomas was reported a long-term therapy with sulindac.‘2B” This series of reports has induced considerable in colon cancer chemoprevention with NSAIDs,
after
interest also en-
couraged by the observation of a significant reduction colon cancer incidence in frequent aspirin users.”
in
We decided, therefore, to make additional measurements of mucosal proliferative activity in patients with FAP, before and after surgery, and to correlate the mucosal proliferation with the occurrence of polyps in the recta1 mucosa under the effect of sulindac.
Materials and Methods Patients The study was conducted on patients with FAP who either had no surgery or had undergone subtotal colectomy Abbreviations used in this paper: FAP, familial adenomatous polyp osis; IRA, ileorectal anastomosis. 0 1994 by the American Gastroenterological Association 0016-5065/94/$3.00
PROLIFERATION AND POLYPS AFTER WLINDAC
February 1994
and IRA. reactions
We excluded to NSAIDs
patients
or peptic
with
ulcers; patients
counts
<3500/mm’,
platelet
count
atinine
leve1 > 1.5 mg/dL; and pacients
had usjed NSAIDs
in the preceding
sent was obtained
from al1 subjects.
The eligible
patients
1 was composed
adenomatous
neal part of the rectum
subtotal
was performed
were treated
hemorrhoidal
with a Aexible Olympus saline solution. informed formed
and l-
sigmoidoscope after cleaning
about the therapeutic
was performed
(Olympus
Optica1 Co.,
the recta1 ampulla
of about
with a diameter surgery,
with a
of the patients,
the number
> 0.5 mm. In the group Houston
in the
valve at a distance
10 cm from the anal verge; in the IRA patients,
the polyps was calculated reference.
taking
were counted.
al1
The size of
the open biopsy forceps as a
At least three recta1 mucosal biopsy specimens
taken from each subject
at a mean distance
sections
previous
samples dently
following
for each patient
study,
by using
for human
Statistical
mucosal
group.
in vitro and
tween groups Statistical
On a set of 43 scores of labeling
subjects
side up. After processing the number
treatment
in a
both
in
were oriented each sample
for
of labeled cells in the crypt, the
of the labeled cells along the crypt, and the total of cells scored per crypt were measured. Data on cel1 were expressed
as labeling
index (number
of la-
beled cells in the crypt divided by number of cells scored times 100)~. Each crypt was also divided into three equal compartments (lower, middle, and upper), and the distribution of proliferating cells along the crypt was expressed as the percentage (of labeled cells in each compartment over the total labeled cells in the crypt section.
by two observers,
we had a
of 0.87 (P < 0.001).
with classica1 analysis of variante
Statistical
Package
(Statistical
MD) and for nonparametric
with the normal
Package
Graphic
comparisons
be-
score exact test using Statxact
(Cytel, Cambridge,
MA).
Results
with a pro-
ac least three specimens
The specimens
The
Analysis
Statgraphic
Figure we studied
every individual
were
specimens
methods,5-7
before and after sulindac
the IRA and non-IRA
proliferation
coefficient
to obtain
codes and were read indepen-
of the same specimens
correlation
crypt
and the counts
before and after therapy.
unknown
by two researchers.
Corp., Rockville,
in colon biopsy described
has been standardized
In the present
position number
was assessed
incorporation
autoradiography,
proliferation
were given
indices
work by US.‘>
vertically
were averaged
value of mucosal
of 7- 10 cm from
of Proliferation
proliferation
autoradiography, that
a mean of 20 -+ 1.4 (SE) longitudinal
was scored for each biopsy specimen,
Data were analyzed
Mucosal
cedure
IRA
of three specimens
using
[‘H)t:hymidine
NON-IRA
flgure 1. Individual values of proliferative actlvity (0) of recta1 mucosa in non-IRA (n = 6) and IRA (n = 14) patients with FAP before and after therapy.2, mean values 5 SE. **P = 0.01, non-IRA patients before therapy vs. IRA patients.
the anal verge.
Measurements
efter
per-
and the size
the polyps were counted
in the recta1 stump
before
therepy
For al1 subjects,
below the superior
polyps present
after therepy
(A.A.), who was not
regimen
The observer was asked to quantify
recta1 ampulla
1
(100
al1 sigmoidoscopies.
that did not undergo
2 bsfare
to sigmoidoscopy
The examination
One of the investigacors
of al1 recta1 polyps
4
vessels.
with sulindac
mg orally twice a day) and were subjected
Germany)
colectomy
on the extraperito-
for 2 months
before and after the treatment. Hamburg,
colorectal 2 was com-
10 cm from the anal verge, preserving
the blood flow from the superior Al1 patients
Group
after surgery was 6.2 years (range,
20 years). The anastomosis
14 i
Group
(9 male, 5 female; mean age, 27.7 years
years)) who underwent
IRA. The mean interval
16
years)); the diag-
of numerous
polyps and on family history.
{range, 12-49
or con-
16
with FAP (2 male, 4
12 -23
on the observation
posed of 14 patients
Informed
into cwo groups.
patients
female; mean age, 17.2 years [range, nosis was based
and cre-
who were pregnant
3 months.
were divided
of 6 non-IRA
l
with leukocyte
< 100,000/mm’,
363
XY
of allergie
a history
IN FAP
mucosa sulindac cantly patients
1 shows
the labeling
in non-IRA
and
IRA
treatment.
The
labeling
reduced
in IRA
(P = 0.01).
indices
patients
indices
patients
compared
A similar
result
of the recta1
before were with
and
after
signifinon-IRA
was obtained
by
our group previously in a study of 17 patients with ulcerative colitis before and after IRA.” In the present study, the non-IRA patients were slightly younger than the IRA patients (mean age, 17.2 vs. 27.7 years). However, because in the preceding study15 the age of the two groups was perfectly balanced, the observed decrease of proliferation after IRA of the present set of data is most likely caused by surgery and not by a slight variation in age. Besides, age would be expected to increase prolifera-
364
SPAGNESI ET AL.
GASTROENTEROLOGY Vol. 106, No. 2
We also measured the cellularity of the crypts, expressed as number of cells per crypt column, but we did not observe I
a
non-IRA
b’
a significant
patients
differente
between
or after sulindac
IRA
treatment
and
(data not
shown).
In
Contrary to the effects on cel1 proliferation, we observed a dramatic reduction in the number of polyps (Table
1). Nevertheless,
significantly
the size of the polyps
was not
varied.
Discussion
a
Most published
b
that changes ment
scientific
reports
in cel1 proliferation
have suggested
precede
of colon cancer both in humans
the develop-
and experimental
animals. Many studies have focused on cellular kinetics in colon mucosa with the aim of discovering early markers of neoplastic
X*
‘a
b’
nn
ments
transformation
and of devising
Accordingly,
patients
index and a displacement
with FAP have a higher labeling of the proliferation
surface of the colon crypts than normal macroscopically factors
normal rectosigmoid
have been associated
with
Figure 2. Distribution of percentage of labeled cells along the crypts of recta1 mucosa of non-IRA (a) and IRA (b) patients with FAP before ) therapy. Data are expressed as mean ? SE; **P -C 0.01, non-IRA vs. IRA patients.
and IRA patients.
even in
an increased activity
risk of is consid-
ered a protective factor against colon cancer development, as documented by the studies on Seventh-Day Adventist
CRYPTUIMPARTENTS
non-IRA
towards the
subjects,
mucosa. Both these
colon cancer.’ On the other hand, low proliferative
tion. Figure 1 also shows that sulindac erratic results on individual proliferation
treat-
that reduce the risk of colon cancer.5m”’
treatment had rates both in
In some patients,
we ob-
vegetarians,
a group with low mortality
from colon can-
25
cer. Our study shows that patients with FAP have a high proliferation rate and a displacement of the proliferative zone towards the surface of the crypts compared normal subjects. The present study also indicates IRA tends to revert to normality of patients with FAP. We previously
reported
the proliferation
that also patients
with that
pattern
with ulcera-
served a decreased proliferation and in others the reverse. The average effect of the treatment was, therefore, null. In the same subjects, we also studied the pattern of proliferation along the crypt, which is reported in Figure 2 as percentage of labeled cells in three crypt compartments.
tive colitis after IRA show a reduction in the labeling index of the recta1 stump and a change of the proliferation pattern, characterized by an increase in the percent of proliferating cells in the lower sections of the crypts.15
It was shown in fact that patients with FAP have a shift of proliferation towards the upper compartments of the crypt.5’6*‘5 In the present study, the percent distribution of labeled cells in the three compartments was increased in the lower compartment and decreased in the upper compartment in IRA patients compared with non-IRA patients (P < O.Ol), confirming previous results’> and showing that IRA normalizes the proliferative pattern of the mucosa and restores the physiological decrease of proliferation towards the surface of the crypt. Figure 2 also shows that sulindac did not modify the distribution of labeled cells along the crypt.
The mechanisms underlying these mucosal changes after IRA in patients with FAP and ulcerative colitis are stil1 not totally clear but are likely the results of variations in intestinal function and content (such as changes in short-chain fatty acids, pH, bile acids, and transit time), factors that modulate mucosal proliferative activ8,26-28 ity in experimental animals and humans. In the present study, we confirmed the previous observations that IRA tends to normalize the labeling index and proliferation patterns of patients with FAP. However, the treatment with sulindac had variable effects, with some patients having decreased proliferation and
PROLIFERATION AND POLYPS AFTER SLILINDAC IN FAP
February 1994
Table1. Effects of Sulindac Treatment
on Recta1 Polyps in Patients
Before and After Surgery
Before therapy
After therapy
No. of polyps Before surgery After surgety
Size (mm)
13.5 -t 7.8 (6-30) 10.08 % 8.05 (0-30)
365
No.
0.9 t 0.6 (0.5-2) 1.0 ? 0.57 (0.5-2)
of polyps
Size (mm)
2.5 2 2.4” (0-7) 2.53 t 3.4” (0.5-10)
0.5 i 0.4 (0-1) 0.57 2 0.54 (0.5-1.5)
NOTE. Results are expressed as mean 2 SD with range in parentheses. Sulindac treatment, 200 mg/day for 60 days. “P i 0.01, compared with the number of polyps in the same patients before therapy, using the normal score exact test.
others the reverse. As a consequente,
the average prolifer-
croscopical
ation rate did not vary significantly
after sulindac
sarily involve an intermediate
ment., neither
was the displacement
wards, higher
crypt
duration
the dosage
lower
of proliferation
levels influenced.
of the treatment than
treat-
In our study,
to-
early steps of the transformation
the
proliferation,
with sulindac
was shorter and
in some previous
reports’“.“.“;
in our study
was likely effective.
because it induced a very dramatic decrease in the expression of polyps, which totally disappeared under the effect of the drug in some of the patients before surgery. A regression and suppression of polyps and micropolyps in patients with FAP has been described after sulindac by other investigators There
as well.‘“-”
was an apparent
lack of association
between
cel1 proliferation and the occurrence of macroscopically evident polyps in our study. The reason for this dissociation is not clear. It has been suggested
that the disorder
in cel1 proliferation is under very strict in patients with FAP2’~‘o; it is possible
genetic control that the effects
of sulindac are thwarted by this factor. On the other hand, although NSAIDs black proliferation in mammalian
cel1 culture
with aspirin the rat.” Tlnerefore,
lines
increases it
in vitro,” proliferation
is possible
that
long-term
treatment
of colon
mucosa
sulindac
and
in
other
NSAIDs control some process leading to the formation of polyps that is independent of cel1 proliferation. For example, sulindac, being a good inhibitor of prostaglandin synthesis, tenance
may interfere
of the stroma
with the formation
and vessel structure
and main-
necessary
sulindac,
for
the polyps to grow. Whereas our data do not indicate an inhibitory effect of sulindac on colon cel1 proliferation, they show a clear inhibitory effect on macroscopically evident polyps. Wh’ether this effect is associated over long term with a lower risk of expression of cancer remains to be shown. A reduction in risk can be anticipated on the assumption of the existente of a multistep process leading from microa.denomas to polyps and eventually to adenomas and adenocarcinomas.1’.‘4 However, the transition from mi-
cancers may not necespolyp :stage. Because some process, such as altered
do not seem to respond
caution
that a reduction
however, other authors have documented a beneficial effect of sulindac in FAP also at lower dosage.‘” Moreover, the dosage of sulindac
lesions to full-grown
should
to the therapy with
be recommended
in the number
in assuming
of polyps after sulindac
is proof of a lower risk of cancer in patienrs
with FAP.
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SPAGNESI ET AL.
hereditary predisposition to colon cancer. Cancer Res 1983;43:1899-1904. Scalmati A. Roncucci L, Ghidini G. Biasco G, Ponz de Leon M. Epithelial cel1 kinetics in the remaining colorectal mucosa after surgery for cancer of the large bowel. Cancer Res 1990; 50:7937-7941. Tonelli F, Elianchini F, Lodovici M, Valanzano R, Caderni G, Dolara P. Mucosal cell proliferation of the recta1 stump in ulcerative colitis patients after ileorectal anastomosis. Dis Colon Rectum 1991; 34:385-390. Klein WA, Miller HH, Anderson M, Decosse JJ. The use of indomethacin, sulindac and tamoxifen for the treatment of desmoid tumors associated with familial polyposis. Cancer 1987; 6012863-2868. McAdam WAF, Goligher JK. The occurrence of desmoids in patients with familial polyposis coli. Br J Surg 1970; 149:215-218. Jones IT, Fazio VW, Weakley FL, Jagelman DG, Lavery IC, McGannon E. Desmoid tumors in familial polyposis coli. Ann Surg 1986;204:94-97. Belliveau P, Graham AM. Mesenteric desmoid tumor in Gardner’s syndrome treated by sulindac. Dis Colon Rectum 1984; 27:5354. Laybayle D, Fischer D, Vielh P, Drouhin F, Pariente A, Bories C, Duhamel 0, Trousset M, Attali P. Sulindac causes regression of recta1 polyps in familial adenomatous polyposis. Gastroenterology 1991; 101:635-639. Waddel RW, Ganser GF, Cerise EJ. Loughry RW. Sulindac for polyposis of the colon. Am J Surg 1989; 157:175-179. Winde G, Gumbinger HG, Osswald H, Kemper F, Bunte H. The NSAID sulindac reverses recta1 adenomas in colectomized patients with familial adenomatous polyposis: clinical results of a dose finding study on recta1 sulindac administration. Int J Coloreet Dis 1993;8:13-17. Giardello FM, Hamilton SR, Krush AJ, Piantodosr S, Hylind LM, Celano P, Booker SV, Rahj Robinson C, Offerhaus GJA. Treatment of colonic recta1 adenomas with sulindac in familial adenomatous polyposis. N Engl J Med 1993;328:1313-1316. Thun MJ, Namboodiri MM, Heath CW. Aspirin use and reduced risk of fatal colon cancer. N Engl J Med 1991;325:1593-1596. Lipkin M, Uehara K, Winawer S, Sauchez A, Bauer C, Philips R, Lynch H, Blattner WA, Fraumeni JF. Seventh-day adventist
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Received March 3, 1993. Accepted September 21, 1993. Address requests for reprints to: Piero Dolara, M.D., Department of Pharmacology and Toxicology, University of Florence, Viale Morgagni 65, 50134 Florence, Italy. Fax: (39) 554361613. Supported by a grant from Consiglio Nazionale delle Ricerche, fïnaliuato A.C.R.O., paper 267.
Recta1 Proliferation and Polyp Occurrence in Patients With Familial Adenomatous Polyposis After Sulindac Treatment MARIA TERESA SPAGNESI,* FRANCESCO TONELLI,’ PIER0 DOLARA,* GIOVANNA ROSA VALANZANO,’ ALESSANDRO ANASTASI,’ and FRANCA BIANCHINI* *Department of Pharmacology and Toxicology and ‘Surgical Unit, Department of Clinical Physiopathology, Florence Italy
Sulindac, a nonsteroidal anti-inflammatory drug (NSAID), decreases the occurrence of polyps in patients with familial adenomatous polyposis (FAP). The effects of colectomy with ileorectal anastomosis (IRA) and sulindac treatment on recta1 mucosa proliferation and polyp occurrence were examined in patients with FAP. Methods: The number and size of recta1 polyps were measured with colonoscopy. The labeling index, the percentage of labeled cells per crypt compartment, was assessed in recta1 biopsy specimens with [3H]thymidine incorporation and autoradiography in 6 non-IRA and 14 IRA patients before and after treatment with 200 mg of sulindac/day for 60 days. Results: The IRA patients had a lower labeling index and a decrease in the percentage of labeled cells in the upper compatiment of the crypt (P < 0.01) relative to non-IRA sub jects. Sulindac did not influence the labeling index and the distribution of labeled cells along the crypt. On the contrary, a dramatic decrease in the size and number of polyps was observed after sulindac treatment (P < 0.001). Conclusions: The persistente of a abnormal mucosal proliferation after sulindac therapy, in spite of the reduction of polyp number, suggests caution in assuming a lower risk of recta1 cancer in patients with FAP. Bac/@ound/Aims:
F
amilial adenomatous polyposis (FAP), if left unattended, inevitably progresses to colorectal cancer. The current surgical treatments of this condition are total colectomy with ileoanal pul1 or ileorectal anastomosis (IRA). The latter
is a simpler
technique
and guarantees
satisfactory functional results in properly selected subjects. However, after IRA, patients with FAP must undergo lifelong surveillance of the recta1 stump for the early detection of new polyps and cancer.‘.’ It has been reported that after IRA, one third of patients with FAP have a complete spontaneous regression of recta1 polyps and lower frequenties of neoplastic transformation when compared with patients affected by the same disease who did not undergo 1RA.s However, surgical treatment with IRA does not annul the risk of colon cancer.” In fact, patients with FAP are characterized by a state of hyperproliferation in the colonic mucosa and by a shift of the proliferative zone to the upper portion
of the colonic
CADERNI,”
University of Florence,
crypts,5.” factors wel1 correlated
risk of cancer development.‘-”
We previously
with the showed
that after IRA, the proliferative pattern of the recta1 stump regresses to normality, but some indicators of an abnormal putrescine a 13%
control
of cel1 division,
and spermine, incidence
reported
for patients
of colon
subjects,2
cancer
after IRA
has been
with FAP in the 25 years following
surgery. ‘JI This frequency non-IRA
such as the polyamines
remain elevated.‘> Accordingly,
is lower than that recorded
but the individual
in
risk of developing
cancer is far from negligible. A few years ago it was reported that some nonsteroidal anti-inflammatory drugs (NSAIDs) were able to control the growth of desmoid tumors in patients affected by FAP or Gardner’s syndrome.‘“-‘” It was later shown that sulindac(ris-5-fluoro-2-methyl-l-~p-(methylsulfynil)benzylidenel
indene-3-acetic
acid), a widely
can also cause polyp regression.‘0-2i ies in patients 6-12 months sulindac
used NSAID,
In one of these stud-
with FAP, al1 polyps disappeared during of therapy with a dose of 300-400 mg
per day.2’ In other recent
studies,
a reduction
of the number and size of adenomas was reported a long-term therapy with sulindac.‘2B” This series of reports has induced considerable in colon cancer chemoprevention with NSAIDs,
after
interest also en-
couraged by the observation of a significant reduction colon cancer incidence in frequent aspirin users.”
in
We decided, therefore, to make additional measurements of mucosal proliferative activity in patients with FAP, before and after surgery, and to correlate the mucosal proliferation with the occurrence of polyps in the recta1 mucosa under the effect of sulindac.
Materials and Methods Patients The study was conducted on patients with FAP who either had no surgery or had undergone subtotal colectomy Abbreviations used in this paper: FAP, familial adenomatous polyp osis; IRA, ileorectal anastomosis. 0 1994 by the American Gastroenterological Association 0016-5065/94/$3.00
PROLIFERATION AND POLYPS AFTER WLINDAC
February 1994
and IRA. reactions
We excluded to NSAIDs
patients
or peptic
with
ulcers; patients
counts
<3500/mm’,
platelet
count
atinine
leve1 > 1.5 mg/dL; and pacients
had usjed NSAIDs
in the preceding
sent was obtained
from al1 subjects.
The eligible
patients
1 was composed
adenomatous
neal part of the rectum
subtotal
was performed
were treated
hemorrhoidal
with a Aexible Olympus saline solution. informed formed
and l-
sigmoidoscope after cleaning
about the therapeutic
was performed
(Olympus
Optica1 Co.,
the recta1 ampulla
of about
with a diameter surgery,
with a
of the patients,
the number
> 0.5 mm. In the group Houston
in the
valve at a distance
10 cm from the anal verge; in the IRA patients,
the polyps was calculated reference.
taking
were counted.
al1
The size of
the open biopsy forceps as a
At least three recta1 mucosal biopsy specimens
taken from each subject
at a mean distance
sections
previous
samples dently
following
for each patient
study,
by using
for human
Statistical
mucosal
group.
in vitro and
tween groups Statistical
On a set of 43 scores of labeling
subjects
side up. After processing the number
treatment
in a
both
in
were oriented each sample
for
of labeled cells in the crypt, the
of the labeled cells along the crypt, and the total of cells scored per crypt were measured. Data on cel1 were expressed
as labeling
index (number
of la-
beled cells in the crypt divided by number of cells scored times 100)~. Each crypt was also divided into three equal compartments (lower, middle, and upper), and the distribution of proliferating cells along the crypt was expressed as the percentage (of labeled cells in each compartment over the total labeled cells in the crypt section.
by two observers,
we had a
of 0.87 (P < 0.001).
with classica1 analysis of variante
Statistical
Package
(Statistical
MD) and for nonparametric
with the normal
Package
Graphic
comparisons
be-
score exact test using Statxact
(Cytel, Cambridge,
MA).
Results
with a pro-
ac least three specimens
The specimens
The
Analysis
Statgraphic
Figure we studied
every individual
were
specimens
methods,5-7
before and after sulindac
the IRA and non-IRA
proliferation
coefficient
to obtain
codes and were read indepen-
of the same specimens
correlation
crypt
and the counts
before and after therapy.
unknown
by two researchers.
Corp., Rockville,
in colon biopsy described
has been standardized
In the present
position number
was assessed
incorporation
autoradiography,
proliferation
were given
indices
work by US.‘>
vertically
were averaged
value of mucosal
of 7- 10 cm from
of Proliferation
proliferation
autoradiography, that
a mean of 20 -+ 1.4 (SE) longitudinal
was scored for each biopsy specimen,
Data were analyzed
Mucosal
cedure
IRA
of three specimens
using
[‘H)t:hymidine
NON-IRA
flgure 1. Individual values of proliferative actlvity (0) of recta1 mucosa in non-IRA (n = 6) and IRA (n = 14) patients with FAP before and after therapy.2, mean values 5 SE. **P = 0.01, non-IRA patients before therapy vs. IRA patients.
the anal verge.
Measurements
efter
per-
and the size
the polyps were counted
in the recta1 stump
before
therepy
For al1 subjects,
below the superior
polyps present
after therepy
(A.A.), who was not
regimen
The observer was asked to quantify
recta1 ampulla
1
(100
al1 sigmoidoscopies.
that did not undergo
2 bsfare
to sigmoidoscopy
The examination
One of the investigacors
of al1 recta1 polyps
4
vessels.
with sulindac
mg orally twice a day) and were subjected
Germany)
colectomy
on the extraperito-
for 2 months
before and after the treatment. Hamburg,
colorectal 2 was com-
10 cm from the anal verge, preserving
the blood flow from the superior Al1 patients
Group
after surgery was 6.2 years (range,
20 years). The anastomosis
14 i
Group
(9 male, 5 female; mean age, 27.7 years
years)) who underwent
IRA. The mean interval
16
years)); the diag-
of numerous
polyps and on family history.
{range, 12-49
or con-
16
with FAP (2 male, 4
12 -23
on the observation
posed of 14 patients
Informed
into cwo groups.
patients
female; mean age, 17.2 years [range, nosis was based
and cre-
who were pregnant
3 months.
were divided
of 6 non-IRA
l
with leukocyte
< 100,000/mm’,
363
XY
of allergie
a history
IN FAP
mucosa sulindac cantly patients
1 shows
the labeling
in non-IRA
and
IRA
treatment.
The
labeling
reduced
in IRA
(P = 0.01).
indices
patients
indices
patients
compared
A similar
result
of the recta1
before were with
and
after
signifinon-IRA
was obtained
by
our group previously in a study of 17 patients with ulcerative colitis before and after IRA.” In the present study, the non-IRA patients were slightly younger than the IRA patients (mean age, 17.2 vs. 27.7 years). However, because in the preceding study15 the age of the two groups was perfectly balanced, the observed decrease of proliferation after IRA of the present set of data is most likely caused by surgery and not by a slight variation in age. Besides, age would be expected to increase prolifera-
364
SPAGNESI ET AL.
GASTROENTEROLOGY Vol. 106, No. 2
We also measured the cellularity of the crypts, expressed as number of cells per crypt column, but we did not observe I
a
non-IRA
b’
a significant
patients
differente
between
or after sulindac
IRA
treatment
and
(data not
shown).
In
Contrary to the effects on cel1 proliferation, we observed a dramatic reduction in the number of polyps (Table
1). Nevertheless,
significantly
the size of the polyps
was not
varied.
Discussion
a
Most published
b
that changes ment
scientific
reports
in cel1 proliferation
have suggested
precede
of colon cancer both in humans
the develop-
and experimental
animals. Many studies have focused on cellular kinetics in colon mucosa with the aim of discovering early markers of neoplastic
X*
‘a
b’
nn
ments
transformation
and of devising
Accordingly,
patients
index and a displacement
with FAP have a higher labeling of the proliferation
surface of the colon crypts than normal macroscopically factors
normal rectosigmoid
have been associated
with
Figure 2. Distribution of percentage of labeled cells along the crypts of recta1 mucosa of non-IRA (a) and IRA (b) patients with FAP before ) therapy. Data are expressed as mean ? SE; **P -C 0.01, non-IRA vs. IRA patients.
and IRA patients.
even in
an increased activity
risk of is consid-
ered a protective factor against colon cancer development, as documented by the studies on Seventh-Day Adventist
CRYPTUIMPARTENTS
non-IRA
towards the
subjects,
mucosa. Both these
colon cancer.’ On the other hand, low proliferative
tion. Figure 1 also shows that sulindac erratic results on individual proliferation
treat-
that reduce the risk of colon cancer.5m”’
treatment had rates both in
In some patients,
we ob-
vegetarians,
a group with low mortality
from colon can-
25
cer. Our study shows that patients with FAP have a high proliferation rate and a displacement of the proliferative zone towards the surface of the crypts compared normal subjects. The present study also indicates IRA tends to revert to normality of patients with FAP. We previously
reported
the proliferation
that also patients
with that
pattern
with ulcera-
served a decreased proliferation and in others the reverse. The average effect of the treatment was, therefore, null. In the same subjects, we also studied the pattern of proliferation along the crypt, which is reported in Figure 2 as percentage of labeled cells in three crypt compartments.
tive colitis after IRA show a reduction in the labeling index of the recta1 stump and a change of the proliferation pattern, characterized by an increase in the percent of proliferating cells in the lower sections of the crypts.15
It was shown in fact that patients with FAP have a shift of proliferation towards the upper compartments of the crypt.5’6*‘5 In the present study, the percent distribution of labeled cells in the three compartments was increased in the lower compartment and decreased in the upper compartment in IRA patients compared with non-IRA patients (P < O.Ol), confirming previous results’> and showing that IRA normalizes the proliferative pattern of the mucosa and restores the physiological decrease of proliferation towards the surface of the crypt. Figure 2 also shows that sulindac did not modify the distribution of labeled cells along the crypt.
The mechanisms underlying these mucosal changes after IRA in patients with FAP and ulcerative colitis are stil1 not totally clear but are likely the results of variations in intestinal function and content (such as changes in short-chain fatty acids, pH, bile acids, and transit time), factors that modulate mucosal proliferative activ8,26-28 ity in experimental animals and humans. In the present study, we confirmed the previous observations that IRA tends to normalize the labeling index and proliferation patterns of patients with FAP. However, the treatment with sulindac had variable effects, with some patients having decreased proliferation and
PROLIFERATION AND POLYPS AFTER SLILINDAC IN FAP
February 1994
Table1. Effects of Sulindac Treatment
on Recta1 Polyps in Patients
Before and After Surgery
Before therapy
After therapy
No. of polyps Before surgery After surgety
Size (mm)
13.5 -t 7.8 (6-30) 10.08 % 8.05 (0-30)
365
No.
0.9 t 0.6 (0.5-2) 1.0 ? 0.57 (0.5-2)
of polyps
Size (mm)
2.5 2 2.4” (0-7) 2.53 t 3.4” (0.5-10)
0.5 i 0.4 (0-1) 0.57 2 0.54 (0.5-1.5)
NOTE. Results are expressed as mean 2 SD with range in parentheses. Sulindac treatment, 200 mg/day for 60 days. “P i 0.01, compared with the number of polyps in the same patients before therapy, using the normal score exact test.
others the reverse. As a consequente,
the average prolifer-
croscopical
ation rate did not vary significantly
after sulindac
sarily involve an intermediate
ment., neither
was the displacement
wards, higher
crypt
duration
the dosage
lower
of proliferation
levels influenced.
of the treatment than
treat-
In our study,
to-
early steps of the transformation
the
proliferation,
with sulindac
was shorter and
in some previous
reports’“.“.“;
in our study
was likely effective.
because it induced a very dramatic decrease in the expression of polyps, which totally disappeared under the effect of the drug in some of the patients before surgery. A regression and suppression of polyps and micropolyps in patients with FAP has been described after sulindac by other investigators There
as well.‘“-”
was an apparent
lack of association
between
cel1 proliferation and the occurrence of macroscopically evident polyps in our study. The reason for this dissociation is not clear. It has been suggested
that the disorder
in cel1 proliferation is under very strict in patients with FAP2’~‘o; it is possible
genetic control that the effects
of sulindac are thwarted by this factor. On the other hand, although NSAIDs black proliferation in mammalian
cel1 culture
with aspirin the rat.” Tlnerefore,
lines
increases it
in vitro,” proliferation
is possible
that
long-term
treatment
of colon
mucosa
sulindac
and
in
other
NSAIDs control some process leading to the formation of polyps that is independent of cel1 proliferation. For example, sulindac, being a good inhibitor of prostaglandin synthesis, tenance
may interfere
of the stroma
with the formation
and vessel structure
and main-
necessary
sulindac,
for
the polyps to grow. Whereas our data do not indicate an inhibitory effect of sulindac on colon cel1 proliferation, they show a clear inhibitory effect on macroscopically evident polyps. Wh’ether this effect is associated over long term with a lower risk of expression of cancer remains to be shown. A reduction in risk can be anticipated on the assumption of the existente of a multistep process leading from microa.denomas to polyps and eventually to adenomas and adenocarcinomas.1’.‘4 However, the transition from mi-
cancers may not necespolyp :stage. Because some process, such as altered
do not seem to respond
caution
that a reduction
however, other authors have documented a beneficial effect of sulindac in FAP also at lower dosage.‘” Moreover, the dosage of sulindac
lesions to full-grown
should
to the therapy with
be recommended
in the number
in assuming
of polyps after sulindac
is proof of a lower risk of cancer in patienrs
with FAP.
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Received March 3, 1993. Accepted September 21, 1993. Address requests for reprints to: Piero Dolara, M.D., Department of Pharmacology and Toxicology, University of Florence, Viale Morgagni 65, 50134 Florence, Italy. Fax: (39) 554361613. Supported by a grant from Consiglio Nazionale delle Ricerche, fïnaliuato A.C.R.O., paper 267.