Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05190250 |
| Other study ID # |
K / DSC / 0042 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
November 1, 2017 |
| Est. completion date |
November 1, 2020 |
Study information
| Verified date |
December 2021 |
| Source |
Jagiellonian University |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
Infertility is a common, worldwide problem. In about 20% of couples, the causative agent of
infertility cannot be identified after routine diagnostic tests. One of the causes of
idiopathic infertility may be implantation disorders.
Implantation can take place at a strictly defined moment in the menstrual cycle, when the
capacity of the blastocyst to implant is overlapped with readiness for its acceptance by the
endometrium, the so-called endometrial receptivity.The time interval in which the endometrium
exhibits this property is called the implantation window.
The acquisition of receptivity by the endometrium is reflected in cellular and structural
changes.The changes taking place at the cellular and molecular levels within the endometrium
are compared to processes such as wound healing and degradation of the matrix during the
neoplastic process.In considering the role of local inflammation in fertility, it is
essential to distinguish between acute and chronic inflammation of moderate or low
intensity.The profile of the molecules seen in a given inflammation depends on the severity,
duration and mechanisms involved in the inflammation process, as well as the ability of the
body's immune system to respond and adapt.IL-18 is a pro-inflammatory cytokine that mediates
a type 1 cellular response. In the context of fertilization, IL-18 is a bivalent cytokine.
Outside of the implantation window, IL-18 acts as an IFN-gamma inducer and is seen as a
detrimental factor in the implantation process. During the implantation window, IL-18 becomes
one of the main factors involved in the proper preparation of the spiral arteries. Histamine
meets all the criteria of an inflammatory mediator. Histamine expression is also expressed in
the endometrium, where it plays the role of a paracrine messenger during embryo
decision-making and implantation. Adequate glucose uptake and metabolism are essential for
the proper differentiation of the uterine endometrium towards a receptive state that allows
the implantation of the embryo. The best described and most abundant glucose transporter in
the endometrial stroma is GLUT1. However, there are no data on the role of GLUT4 in
undetermined infertility.
GLUT4 is one of the better studied transporters because of its major role in whole body
glucose homeostasis and the pathogenesis of type II diabetes.
Aims:1. Analysis of the level of interleukin 18 and histamine as molecules with a postulated
role in the implantation process in the receptive endometrium in women with primary
infertility of unknown etiology and comparing it to the group of women with naturally
conceived offspring.
2. Assessment of the correlation of the levels of interleukin 18 and histamine in the
receptive endometrium and in the blood as an attempt to find a diagnostic useful marker of
receptivity.
3. Analysis of GLUT4 level in the receptive endometrium between two groups.
Materials and Methods:
Patients recruited from among women hospitalized at the CMUJ Gynecological Endocrinology
Clinic for hormonal diagnostics.
1. The patient's visit during the implantation window (appropriate time of the cycle
determined on the basis of ultrasound ovulation monitoring)
2. Endometrial aspiration biopsy, venous blood collection (5 ml). Preparation of material.
3. Analysis of the collected material.
Description:
Infertility affects approximately 8 to 12% of reproductive age couples worldwide, equivalent
to more than 186 million people.
In approximately 20% of couples, the causative agent of infertility cannot be identified
after routine diagnostic tests. One of the causes of idiopathic infertility may be disorders
of the implantation process.
Implantation can take place at a specific point in the menstrual cycle, when the capacity of
the blastocyst to implant is overlapped with readiness for its acceptance by the endometrium,
the so-called endometrial receptivity.
The time interval in which the endometrium exhibits this property is called the implantation
window.
The implantation window in humans is a period of 3 to 6 days, it falls on half of the
secretory phase - that is, 6 to 10 days after the LH peak.
The acquisition of receptivity by the endometrium is reflected in cellular and structural
changes.
The processes are hormonally controlled by estrogens and progesterone of ovarian origin. In
addition, locally produced signaling molecules such as cytokines, growth factors, and lipid
mediators via autocrine, paracrine and juxtacrine signaling are important.
Genetically receptive and decisive are driven by the Hoxa10 and Hoxa11 homeobox genes, whose
expression is increased by the action of steroid hormones. Changes at the cellular and
molecular levels within the endometrium are compared to processes such as wound healing and
degradation of the matrix during the process of cancer invasion.
Among the cells of the immune system infiltrating the endometrium, mononuclear cells
dominate: macrophages, lymphocytes and NK cells.
In considering the role of local inflammation in fertility, it is essential to distinguish
between acute and chronic inflammation of moderate or low intensity.
In the acute phase of the inflammatory response, cells of the immune system migrate to the
site of injury in a carefully planned sequence of events facilitated by soluble mediators
such as cytokines, chemokines, and acute phase proteins. Depending on the severity of the
injury, this acute phase may be sufficient to repair the damage and initiate healing
processes.
Prolonged inflammation, as a result of prolonged exposure to stimulation or an inappropriate
response against one's own tissues, can lead to a chronic phase, in which tissue damage and
fibrosis can occur.
The profile of the molecules seen in a given inflammation depends on the severity, duration
and mechanisms involved in the inflammation process, as well as the ability of the body's
immune system to respond and adapt.
Aim of the study was to investigate whether the levels of selected inflammatory molecules -
interleukin18 and histamine, differ in the population of women with undetermined infertility
compared to women with naturally conceived offspring.
Materials and methods A prospective, cross-sectional study was conducted. The study design
received a positive opinion of the Bioethics Committee of the Jagiellonian University No.
1072.6120.78.2017 dated June 29, 2017 The funds were obtained from the grant No. K / DSC /
00421 of the Ministry of Science and Higher Education. The study group consisted of 58 women
diagnosed with primary infertility, and a control group consisted of 8 patients with
naturally conceived offspring. Patients were recruited from among women hospitalized at the
Gynecological Endocrinology and Gynecology Clinic, consulted at the Gynecological
Endocrinology Clinic and diagnosed under the Comprehensive Reproductive Health Program in the
period from November 2017 to March 2020.
The inclusion criteria for the study group were met by women of reproductive age (18-40 years
old) suffering from primary infertility (unsuccessfully trying to become pregnant for more
than a year), menstruating regularly, not using hormone therapy.
The exclusion criteria were: established male factor of infertility, tubal factor,
endometriosis, inflammation in the pelvic area - currently and in the history, hormonal
background of infertility, obesity, insulin resistance, status post at least one miscarriage
and chronic autoimmune diseases.
The inclusion criteria for the control group were met by patients of reproductive age (18-40
years) with naturally conceived offspring up to three years of age, with regular
menstruation. The exclusion criteria were: condition after surgery on the uterus, including
curettage of the uterine cavity, endometriosis, pelvic inflammation - present and in the
history, at least one miscarriage, obesity, insulin resistance, chronic autoimmune diseases,
breastfeeding.
Patients from both groups recruited for the study were examined during the implantation
window. The appropriate timing of the cycle was determined by ultrasound ovulation
monitoring. Patients reported around day 10 of the cycle to observe the growth of the
dominant follicle. The examination was repeated after 3-4 days. If the dominant follicle
growth was confirmed, the patient performed a urine LH test at home 16 days before the
expected onset of menstruation. Patients reported 6-8 days after the LH peak or, in case of
questionable test result, in the middle of the luteal phase determined by the reported length
of the menstrual cycles - 8-4 days before the day of the expected period. During the visit,
an ultrasound examination was performed to confirm past ovulation (observation of the corpus
luteum in an identical ovary, endometrium at least 10 mm wide).
The patients were informed about the necessity to give up intercourse in the cycle in which
the study was conducted, which was confirmed in the study documentation. Patients who did not
accept this requirement could not be admitted to the study. During the visit, after ovulation
was confirmed, endometrial aspiration biopsy was performed using a plastic pipette with a
diameter of approx. 3 mm (Pipelle Endometrial Suction Curette). If there were difficulties in
penetrating the cervical canal with a pipette, the upper lip of the cervix was gripped with a
clamp. In the case of severe pain in the patient or the inability to penetrate the cervical
canal, collection of the material was discontinued. Immediately after the examination,
patients were asked to rate the intensity of pain during the procedure numerically on the
numerical rating scale (NRS), where 0 is no pain at all and 10 is the worst pain imaginable.
There were no complications in any of the patients. The collected endometrial sample was
preserved in a solution of 10% neutral, buffered formalin at room temperature, and then
transferred to the CMUJ Clinical and Experimental Pathology Department for fixation in
paraffin blocks.
On the same day, a 5 ml venous blood sample on EDTA was collected from each patient. The
blood was centrifuged for 15 minutes at 3000 rpm, and the serum was sent to the Department of
Clinical Biochemistry of the Jagiellonian University Medical College for the determination of
IL-18 and histamine levels.
Immunohistochemistry Tissue material was fixed in formaldehyde for 24 hours. Then it was
dehydrated in 70% ethanol solution and then embedded in paraffin. Tissues were sectioned 4 µm
thick and mounted on silanized slides. The sections were divided into three equal sets.
Paraffin preparations were dewaxed (3 xylene exchanges at room temperature; the first
exchange - 10 minutes, the second and third exchange after 15 minutes) and rehydrated (3
alcohol exchanges at room temperature, 5 minutes each). Then the preparations were incubated
at room temperature for 10 min. in a 3% H2O2 solution to block endogenous peroxidase. Slides
were rinsed in distilled water and incubated with TBS for 5 minutes. Then the slides were
unmasked with citrate buffer pH 6.0 in a water bath at 97 ° C. After the preparations were
unmasked, the Ultra Vision Protein Block preparation (Thermo Scientific) was applied for 5
min. at room temperature in a humid chamber. Then the appropriate antibody was applied and
incubated at room temperature in a humid chamber for a specified time (Table 1). The first
set of sections was incubated with IL-18 reactive rabbit polyclonal antibodies (Recombinant
IL18 (Tyr37 ~ Asp193), Cloud-Clone Corp., 0.33 mg / ml Cat. No. PAA064HU01) at a dilution of
1:00 for 60 min. The second set was incubated with histamine reactive rabbit polyclonal
antibodies (Recombinant human histamine (Met1 ~ Ile163), Cloud-Clone Corp., 0.35mg / ml,
catalog no. PAA927Ge01) at a dilution of 1: 100 for 30 min. The third set was incubated with
rabbit polyclonal antibodies (Recombinant human GLUT4 (Met1 ~ Ile163) Cloud-Clone Corp.,
catalog no. PAC023HU01) at a dilution of 1:50 for 30 min. Excess antibody was washed with TBS
buffer and Post antibody blocking for Bright Vision plus (BrightVision + Goat anti-mouse /
rabbit HRP - ImmunoLogic kit) was applied. We incubate in a humid chamber at room temperature
for 20 minutes.
Excess reagent was washed off with TBS buffer and a poly-HRP-GAMs / Rb IgG preparation
(BrightVision + Goat anti-mouse / rabbit HRP - ImmunoLogic kit) was applied. Incubated at
room temperature in a humid chamber for 30 minutes. Excess reagent was washed off with TBS
buffer and DAB Quanto (Thermo Scientific) was applied. Incubated at room temperature in a
humid chamber for about 5 minutes. Then, the excess reagent was rinsed with distilled water
and the slides were colored with hematoxylin (Thermo Scientific). The preparations were
dehydrated by carrying out a series of three changes of alcohol and xylene in increasing
concentrations. Closed with a coverslip (CYTOSEAL by ThermoScientific). Expression of each
cytokine was assessed semi-quantitatively as the number of positive cells per square
millimeter in the analyzed sample, calculated using an image analyzer.
IL-18 and histamine in the blood Serum IL-18 measurement was performed by ELISA using human
recombinant IL-18 (Human IL-18 ELISA Kit, Biorbyt, catalog no. Orb50153). Blood samples and
reagents were warmed to 37 ° C and then diluted 1: 2 with the diluent using 50 µL of buffer
with complete and uniform mixing. The solution was dispensed 0.1 ml per well. The microliter
plate with the wells was covered with a lid and incubated at 37 ° C for 90 min. The plate was
then dried, 0.1 ml of biotinylated anti-human IL-18 antibody solution was added to each well
and incubated at 37 ° C for 60 min. The plate was then washed three times in 0.01 M TBS (TRIS
buffered saline), each time leaving the wash buffer in the well for 1 min. The buffer was
removed and the plate was dried, then 0.1 ml of prepared avidin-biotin-peroxidase (ABC)
solution was added to each well and the plate was incubated at 37 ° C for 30 min. The plate
was rinsed again, this time 5 times with 0.01 M TBS, and the washing buffer was left in the
wells for 1-2 min each time. The buffer was removed and the plate was dried, then 90 µl of
TMB dye was added to each well and the plate was incubated at 37 ° C for 10 min. 0.1 ml of
TMB contrast dye solution was added to each well and the absorbance was immediately measured
at 450 nm. Serum histamine levels were measured by ELISA using the Histamin ELISA
Immundiagnostik reagent, catalog number K 8212. The washing buffer concentrate (WASHBUF B)
was diluted 1:10 in pure water. Reagents were brought to room temperature. The plasma samples
were mixed with the derivatization reagent. The derivatized sample was then incubated on a
horizontal shaker together with a peroxidase labeled polyclonal histamine antibody on a
histamine derivative coated ELISA plate for 1 hour at room temperature. Then the contents of
the wells were washed 5 times with 250 µl of the washing buffer. After the last step,
residual buffer was removed with tissue paper. Then 100 μl of substrate (SUB) was pipetted
into each well, incubated for 15 minutes at room temperature, protected from light. 100 µl of
the contrast dye solution was added to each well. The absorbance was measured immediately at
450 nm. The results are expressed in picograms per milliliter.
Statistical analysis. Statistical analysis was performed using the Statistica program
(StatSoft 13.3). The Shapiro-Wilk normality test of the examined variables and the presented
frequency charts showed that the distribution of the variables was not normal. The
non-parametric Wald-Wolfowitz and U Mann-Whitney tests were used to compare the study group
with the control group. The significance test of the correlation coefficient was based on the
statistics for the Student's t-distribution.
