Cutaneous Leishmaniasis Clinical Trial
Official title:
Double Blind, Randomized Controlled Trial, to Evaluate the Effectiveness of a Controlled Nitric Oxide Releasing Patch Versus Meglumine Antimoniate in the Treatment of Cutaneous Leishmaniasis
Cutaneous leishmaniasis is a worldwide disease, endemic in 88 countries, that has shown an
increasing incidence over the last two decades. So far, pentavalent antimony compounds have
been considered the treatment of choice, with a percentage of cure of about 85%. However,
the high efficacy of these drugs is counteracted by their many disadvantages and adverse
events. Previous studies have shown nitric oxide to be a potential alternative treatment
when administered topically with no serious adverse events. However, due to the unstable
nitric oxide release, the topical donors needed to be applied frequently, making the
adherence to the treatment difficult. The electrospinning technique has allowed the
production of a multilayer transdermal patch that produces a continuous and stable nitric
oxide release. The main objective of this study is to evaluate this novel nitric oxide
topical donor for the treatment of cutaneous leishmaniasis.
A double-blind, randomized, double-masked, placebo-controlled clinical trial, including 620
patients from endemic areas for leishmaniasis in Colombia was designed to investigate
whether this patch is as effective as meglumine antimoniate for the treatment of cutaneous
leishmaniasis but with less adverse events. Subjects with ulcers characteristic of cutaneous
leishmaniasis will be medically evaluated and laboratory tests and parasitological
confirmation performed. After checking the inclusion/exclusion criteria, the patients will
be randomly assigned to one of two groups. During 20 days Group 1 will receive
simultaneously meglumine antimoniate and placebo of nitric oxide patches while Group 2 will
receive placebo of meglumine antimoniate and active nitric oxide patches. During the
treatment visits, the medications will be administered daily and the presence of adverse
events assessed. During the follow-up, the research group will visit the patients at days
21, 45, 90 and 180. The healing process of the ulcer, the health of the participants,
recidivisms and/or reinfection will also be assessed. The evolution of the ulcers will be
photographically registered. In the case that the effectiveness of the patches is
demonstrated, a novel and safe therapeutic alternative for one of the most important public
health problems in many countries will be available to patients.
BACKGROUND
Cutaneous Leishmaniasis (CL) is a worldwide disease that is endemic in 88 countries [1] . It
is estimated that 1.5 million people suffer from CL annually and that more than 350 million
are at risk of contracting the infection [2-4]. In America, 60,000 new cases of CL are
reported annually [5], being endemic in 20 of its 22 countries and in 2 islands of the
Caribbean [2]. Currently, CL has affected more than 500 U.S. Army soldiers serving in Iraq
[6]. In the Andean region, the incidence of Leishmaniasis has been increasing dramatically
over the last two decades; reaching more than 14,000 cases per year from 1996-98 [7]. In
Colombia 6,500 cases have been reported [8]. The increase in the reported cases of CL in
Colombia has been related to factors such as migration, deforestation, the multiplication of
illicit plantations, the armed political conflict and the behavioral changes of the vector.
The main strains of Leishmania in Colombia are L. panamensis, L. brazilensis, L. infantum
and L. guyanensis, which are distributed throughout the entire national territory,
predominantly in the rural areas [10]. CL is caused by intracellular protozoan parasites of
the genus Leishmania [1] and is transmitted to humans through the bite of a small percentage
of the species of phlebotomus and lutzomyia sandflies classified to date [10]. In the
digestive system of the sandflies, this dimorphic parasite presents an extracellular
flagellated form called a promastigote, which upon its release in the host blood, is
phagocytized by the macrophage, losing its flagella and turning into an amastigote [12].
Dogs, rodents and didelphidae are the natural hosts of the parasite while man is an
incidental host [11]. This zoonosis has suffered an interesting urbanization phenomenon,
changing from an eminent rural entity affecting mainly men of an active age, to a disease
that is affecting all people, especially children [8,9]. The characteristic lesions of this
disease are ulcers that heal spontaneously over a period of three months to a year,
depending on the isolate, and that leave a flat, atrophic and depigmented scar [13-15]. The
CL, especially the one produced by L. brazilensis can evolve into mucocutaneous
Leishmaniasis (MCL), which has a worse prognosis owing to the deforming character of its
lesions [16]. The spontaneous cure of these lesions allows for the acquisition of partial
resistance to reinfection, which could explain the higher pathogenicity observed in the
children and young adult population [9]. Previous studies have shown a higher incidence of
CL and a poor response to treatment in the children population [17]. The program of
epidemiological vigilance in Colombia requires that the probable cases of CL (identified by
ulcer features and by the patient's origin) be confirmed by microscopic direct examination
of a secession sample obtained from the ulcer, if these are negative, by biopsy of the
wound. Once confirmed, the cases must be notified to the Local Health Secretary using
clinical-epidemiological records. This institution, in charge of the epidemiological
vigilance, studies the sources of transmission and distributes the medication to the people
affected. Currently, various aspects are considered when treating CL, among which, the risk
of developing MCL, the grade, localization, number, size, evolution and persistence of the
lesions, are the most important [18]. For more than 60 years, the pentavalent antimony
compounds: sodium stibogluconate, (Pentostan®, produced by Glaxo-Wellcome) and meglumine
antimoniate, (Glucantime®, produced by Sanofi-Aventis) have been considered the treatments
of choice for this disease [19]. Studies made in Colombia reported a percentage of cure of
85%, using meglumine antimoniate [20,21]. Despite the fact that the efficacy of these drugs
is high, they present many disadvantages such as parenteral administration, and, reversible
secondary effects such as nausea, vomiting, muscular and abdominal pain, cardiac problems, a
rise in the concentration of hepatic aminotransferases, and chemical pancreatitis [21,22].
Additionally, the adherence to the treatment is affected by its duration (several weeks) and
its availability by the restriction in its distribution. Therapeutic alternatives of second
line have been proposed; amphotericin B and pentamidine have been used with excellent
results, nevertheless their high cost, little availability, the necessity to hospitalize the
patients for their administration and the severity of their secondary effects have limited
their use [23,24]. In the last decade new treatments for CL have been developed, using oral
agents such as mefloquine, itraconazole, miltefosine, paromomycin, ketoconazole, allopurinol
and dapsone, however, they have not shown enough evidence of their effectiveness
[19,21,25,26]. In an effort to develop a topical treatment for CL, paromomycin has been used
in different preparations. However, rates of curation achieved with this medication have not
been higher than conventional treatments, even when compared with placebo [27,28]. In
several studies, in vitro and in vivo, it has been demonstrated that nitric oxide (NO) is
effective to eliminate various strains of Leishmania in its amastigote form [29-35]. The
production of NO from the oxidation of L-arginine caused by the inducible nitric oxide
synthase (iNOS) constitutes one of the most important defense mechanisms of the macrophages
[36], in which two oxidative forms of defense against Leishmania have been identified.
During the first phase of infection, in response to the phagocytosis process, some
promastigotes are eliminated due to the release of the superoxide ion, a process which is
catalyzed by the NADPH oxidase [29]. Those promastigotes that survive this defense mechanism
evolve into amastigotes, activating the production of IL-12 in the macrophages and promoting
the presentation of the antigens of Leishmania [29] to the T helpers 1 lymphocytes that
enhance the cytotoxic activities of the macrophages toward the intracellular parasites via
the interferon gamma (INFγ) and the tumor necrosis factor alpha (TNFα) by promoting the
production of NO catalyzed by iNOS [31-33]. A recent study shows a higher activity of iNOS
in the macrophages of subjects infected with CL, suggesting a vital role of NO in the
immunological activity against Leishmania [34]. In Studies with rodents resistant to
Leishmania infection (C57BL/6), where L. major, L. chagasi or L. donovani were inoculated,
the application of iNOS inhibitors like NG-monomethyl-L-arginine (L-NMMA) caused a higher
rate of survival and virulence of the parasites in macrophages [33,35,37,38]. After
inoculating L. major in mice with the genetic susceptibility to develop infections with
Leishmania (BALB/C), no activity of iNOS was observed. However, the application of IL-12,
was able to control the infection by activating iNOS [31]. In humans, several clinical
trials have been realized with topical treatments containing NO donors [39,40]. In Ecuador,
our group developed and tested a NO generating topical cream with
S-nitroso-N-acetylpenicillamine (SNAP), evidencing a beneficial effect in the management of
this type of ulcers with no reports of any serious adverse event. Nevertheless, due to the
unstable nitric oxide release, the cream had to be applied frequently (4 times a day) making
the adherence to the treatment difficult [39]. In Syria, another group used potassium
nitrate acidified with salicylic acid and ascorbic acid for the topical treatment of L.
tropica [40]. In vitro, this NO generating mixture destroyed the amastigotes and
promastigotes of Leishmania; however, in vivo, the study of 40 patients presented
inconsistent results, reducing the size of the ulcer in 28% of the subjects and healing only
12%. The discrepancy in these results is believed to be due to the technique used to obtain
the NO. The acidification of nitrite produces an instant blast of NO, but its release is not
maintained over a long period of time [40]. The difficulty of controlling the liberation of
NO has created the necessity of looking for new techniques to regulate its release. The
nanofiber polymers produced by the electrospinning technique have been studied in order to
guarantee the constant release of pharmaceuticals on the lesion. In the electrospinning
process, a high voltage is used to create an electrically charged jet of polymer solution,
which dries and solidifies to leave behind a dry polymer fiber [41]. As this jet travels
through the air, the solvent evaporates leaving behind a charged fiber that can be
electrically deflected and collected on a metal screen [42,43]. Fibers with a variety of
cross sectional shapes and sizes are produced from different polymers. With this technique,
the encapsulation or entrapment of several pharmaceuticals, enzymes and proteins has been
successful. In a previous study, nanofiber patches were successfully used as releasing
vehicles of tetracycline hydrochloride. The release of tetracycline was constant for a
period of 5 days [41;43]. Using the same model, a multilayer transdermal patch has been
produced, in which nitrite is bound to an ion exchange resin (DOWEX) and electrospun into a
polyurethane nanofibers layer. A solution containing Waterlock® superabsorbent and
polyurethane is electrospun on top of the nitrite-DOWEX layer. The ascorbic acid entrapped
in the polyurethane solution is electrospun onto a third layer, with another layer of
Waterlock® superabsorbent and polyurethane as the fourth and final one. Upon hydration, this
Nitric Oxide Releasing Patch (NOP) produces a stable release of 3.5 µmol of NO during 12 hrs
[41,44,45]. In a pilot study, developed in Landazuri, Santander, Colombia, a
placebo-controlled clinical trial was conducted with 35 patients who presented 68 ulcers
produced by L. panamensis. Using the NOP, a 65% improvement was observed in the treated
ulcers, with only a 25% improvement in the placebo group (p=0.001). In this pilot study the
unique adverse event described was pruritus in the area where the patch was applied
(unpublished data). Taking into account the wide distribution of CL, the changes in its form
of transmission and the difficulty related with the availability of medication, this study
proposes to investigate whether the NO donor transdermal patch, produced by electrospinning
is, at least, as effective as the meglumine antimoniate for the treatment of CL, with less
adverse events and a lower cost, constituting therefore an effective therapeutic
alternative. In case that the effectiveness of the NOP is demonstrated in this study, a
novel and safe therapeutic alternative of easy access and higher adherence for one of the
most important public health problems in our country will be made available.
OBJECTIVES
General Objective
To evaluate the effectiveness and safety of NOP in the treatment of CL compared with
meglumine antimoniate (Glucantime®).
Specific objectives
1. To evaluate the healing rate of CL ulcers using a NOP compared with the plan of
treatment with meglumine antimoniate recommended by the health ministry.
2. To identify adverse events associated with the application of NOP and compare them with
the ones produced by the treatment with meglumine antimoniate.
3. To identify and compare the recidivisms that may occur with both NOP and meglumine
antimoniate.
4. To advance in the search of a therapeutic alternative for CL in Colombia.
DESIGN
Double blind, randomized, double-masked, placebo-controlled clinical trial, comparing nitric
oxide releasing patches with meglumine antimoniate.
SAMPLE SIZE
The sample was calculated according to the arccosine formula using a power of 80% and a type
1 error of 0.05%. Assigning a successful rate of 85% for meglumine antimoniate and 75% for
NOP, 558 patients will be needed. After adjustment for a loss rate of 5%, the total of
patients that must be recruited is 620 (310 patients per treatment group).
POPULATION
The population will be composed from two regions of Colombia. The first one is an endemic
zone in Santander, Colombia, located between the Magdalena Valley and the East Mountain
Range, which includes the municipalities of Landazuri, El Carmen, San Vicente, El Playon and
Rionegro. The second region is an endemic zone in North Tolima, which includes the
municipalities of Chaparral, San Antonio, Libano, Falan, Palocabildo and Mariquita.
SELECTION OF THE PATIENTS
Inclusion Criteria
1. Men and women between 18 and 50 years old
2. Cutaneous ulcers of more than two weeks of evolution
3. Positive parasitological diagnosis for CL
4. Patients that voluntarily agree to participate in the study and sign the informed
consent.
5. Disposition to attend all the visits punctually (initial, treatment and follow-up)
6. Acceptation of not using any other treatment for CL while in the study
Exclusion Criteria
1. Pregnant women
2. Presence of any condition or disease that compromises the patient immunologically (i.e.
diabetes, cancer, etc.) or, any other, that, based on the judgment of the researcher,
could alter the course of CL.
3. Diffuse CL or more than five active lesions.
4. Mucocutaneous leishmaniasis (no lesion must be located less than 2 cm from the nasal,
uro-genital, and/or anal mucous membranes or from the edge of the lips).
5. Visceral leishmaniasis
6. Complete or incomplete treatment with antimony compounds in the last three months.
7. Patients with history of hepatic, renal or cardiovascular disease.
8. Mentally or neurologically disabled patients that are considered not fit to approve
their participation in the study.
STUDY DEVELOPMENT
Logistic Phase
This phase will last 4 months and will include the following activities:
1. Training of the personnel that will participate in the study.
2. Acquisition of the materials required for the development of the project.
3. Elaboration of flyers, promotional and educative material, procedures manual and case
report forms (CRFs).
4. Treatment randomization. The treatment randomization will be realized by the
epidemiologist of the Cardiovascular Foundation of Colombia. This randomization will be
done in blocks in order to keep the size of the treatment groups similar, to avoid long
sequences of the same treatment and to balance when possible some of the bias inherent
to the simple randomization process. Additionally, this randomization in blocks will
facilitate the execution of interim analyses.
Recruitment Phase
This phase will take 22 months. In the selected municipalities, the health personnel that
work in hospitals and health centers will receive training regarding the disease and the
study methodology. Simultaneously an epidemiological focus study will be done with the
leaders of the community and the health personnel to identify the geographic and demographic
conditions with the purpose of developing strategies for the recruitment of possible cases
of leishmaniasis. Subsequently, the subjects that present active ulcers with more than 2
weeks of evolution, with or without parasitological confirmation of CL, will be invited by
the health promoters to attend the screening visit (Table 1).
Screening Visit
During this visit a complete clinical history will be elaborated and data about antecedents
of leishmaniasis obtained (administered treatment, localization, number of lesions, etc). A
full medical evaluation will be realized based on universally accepted techniques. The
inclusion/exclusion criteria will be applied and the selected candidates informed about the
study after which they will sign an informed consent. For those subjects with ulcers of more
than two weeks of evolution without parasitological diagnosis a direct test will be
performed by the parasitologist. If the first direct test is negative, it will be repeated
up to three times; after which, in case of negative results, a biopsy will be performed. In
case leishmaniasis is not confirmed the patient will be remitted to the original health
center.
Initial Visit
The included patients will be randomly assigned in one of two groups. A culture in
Novy-Nicole-McNeal (NNN) medium will be taken for strain identification and a blood sample
withdrawn from the antecubital vein for hepatic enzymes, creatinine, and pancreatic amylase
determination. During this visit, a complete medical evaluation will be performed, the ulcer
will be measured and a picture will be taken. Before taking the picture, a graduated rule
will be placed next to the ulcer along with a sticker marked with the identification code of
the participant, and the date of the visit. The first NOP (active or placebo) will be
applied covering the lesion and the first shot of meglumine antimoniate (active or placebo)
administered. The patients will receive information on how not to damage the patches and how
to identify and report adverse events. To help the patients to do so, they will receive a
diary to register them. The two groups randomly composed will be divided as follows:
Group 1: During 20 days this group will receive simultaneously intramuscular (IM) meglumine
antimoniate (Glucantime® 20 mg/kg/day with a maximum dose of 3 ampules per day); and a NOP
placebo.
Group 2: During 20 days this group will receive simultaneously placebo of IM meglumine
antimoniate (5-15cc/day) and an active NOP.
Treatment Visits
The patients will visit the health center daily during 20 days to receive both the NOP
(placebo or active) and meglumine antimoniate (placebo or active). Daily, the subjects and
their adherence to the treatment will be assessed and the data collected. If any adverse
event is detected, the patient will be referred immediately to the medical staff who will
make an evaluation and report it to the adverse event committee that will take the final
decision in each case.
Follow-up visits
This phase will last 10 months. During the follow-up, the patients will be seen by the
research group in 4 opportunities. The first visit will take place the day after the end of
the treatment (day 21) in which new blood samples will be taken for biochemical
determinations. The second, third and fourth visits will be realized on day 45, 90 and 180
respectively. During these visits the healing process of the ulcer, the presence of
recidivisms and/or reinfection and the health of the participants will be assessed. The
evolution of the ulcers will be photographically registered.
The maximum and minimum diameters of the ulcer will be measured using a graduated ruler, and
the induration using the ballpoint pen technique. The ulcer and induration areas will be
calculated separately, and then registered in the CRF. The evaluation of the clinical
response will be based on the ulcer showing the least improvement.
1. Complete clinical response: Complete reepithelization of the ulcer and disappearance of
the induration.
2. Clinical Improvement: Reduction of more than 50% of the ulcer and the induration areas
in relation to the last clinical evaluation.
3. Absence of clinical response: Increase or reduction of less than 50% of the ulcer and
the induration areas in relation to the last clinical evaluation.
4. Therapeutic failure:
1. Increase in the size of the ulcer by more than 50% in relation to the last
clinical evaluation
2. Presence of the ulcer three months after the beginning of the treatment.
3. Reactivation: Appearance of a lesion on the edge or in the center of the scar,
with positive parasitological diagnosis, after a period of complete
reepithelization.
4. Affection of the mucous membranes: Presence of affections of the mucous membranes
during the treatment, at the end of it or in the follow-up visits.
5. Reinfection: Activation of an ulcer in an area different from the original lesion.
For subjects whose treatment will have been considered a failure the code will be broken and
they will be remitted to their original health center to look for another therapeutic
approach.
Procedures
Physical Examination
A complete physical examination will be realized and vital signs will be measured.
Blood Samples Withdrawn
Blood samples will be withdrawn from the antecubital vein to perform the following
biochemical analyses:
1. Creatinine by spectrophotometry
2. Alanine transaminase (ALT) by spectrophotometry
3. Aspartate transaminase (AST) by spectrophotometry
4. Pancreatic amylase by spectrophotometry
Sampling Technique for the Direct Test of CL
A direct test is performed to confirm the presence of cells with amastigotes in a dermis
scrape[46,47]; the sample must be, in so far as it is possible, free of blood, cellular
detritus or pus. If the patients present several lesions, the sample must be taken from the
one with the shortest time of evolution, the biggest induration area and/or the least
purulent discharge. If the lesion has a scab it must be removed to improve the quality of
the sample. The sample can be taken from the active edge or from the bottom of the ulcer.
When the sample is taken from the active edge asepsis must be realized with alcohol at 70%
and hemostasis then performed using the first and second fingers to make sure that there is
no blood in the sample. A small incision of about 3mm in length and depth is made with a
scalpel in the active edge parallel to the edge of the ulcer. With the sharp side of the
scalpel, a scrape is done in the dermic wall of the incision to obtain tissue. The extracted
material is extended on two microscope slides. The sample is dried at room temperature, and
then fixed with methanol and stained with Giemsa, Wright or Field. Using immersion oil the
sample is observed under a microscope with a 100X lens, the presence of amastigotes of
Leishmania assessed and their structure verified (nucleus, kinetoplast and cell membrane).
If the sample is taken from the center of the lesion the same hemostatic technique must be
used, the scab removed, and the bottom of the ulcer well cleaned using the sharp side of the
scalpel to prevent the presence of cellular detritus and/or purulent material. This
procedure must be continued until the granulomas are seen at the bottom. With the same
technique used to process the samples from the active edge the presence of amastigotes of
Leishmania is verified.
Technique for the sampling of cultures
The sample for the culture may be obtained by suctioning the ulcer active edge or by
extracting a fragment of tissue which is then macerated in a phosphate-buffered saline
solution (PBS) with antibiotics (1000 UI of crystalline penicillin per cc), before it is put
in the culture medium. A tuberculin syringe with a thin needle (26G), containing 0.3 cc of
PBS solution with antibiotics is used in the suction technique. Previous asepsis of the
ulcer with alcohol at 70%, a needle is introduced into the dermis and through rotating
movements a small amount of tissue is macerated by the needle bevel during about a minute,
after which it is suctioned into the syringe. The sample is deposited in aseptic conditions
into a NNN culture medium and incubated at 26ºC during 4 weeks [46,47]. Every week a drop is
extracted from the culture medium and placed between two slides to be observed under a
microscope. In case that promastigotes are not found, the cultures are rejected as negative
[46]. The strains are identified by species using the monoclonal antibodies developed by Dr.
Diane Mc Mahon Pratt [48,49].
Evaluation and management of adverse events
During the treatment and the follow-up visits, the patients will be asked about adverse
events. Each adverse event will be classified by the physician as serious or
non-serious(Table 2 and 3). A serious adverse event should meet one or more of the following
criteria:
1. Death
2. Life-threatening (i.e., immediate risk of death)
3. In-patient hospitalization or prolongation of existing hospitalization
4. Persistent or significant disability/incapacity The presence of a serious adverse event
that puts the patient's life at risk and/or requires immediate medical or surgical
procedure will call for the discontinuation of the treatment and the initiation of the
pertinent medical management of the patients. The investigator will notify the Adverse
Event Committee (AEC) of the FCV of any serious adverse event within 24 hours of
learning about it.
A non serious adverse event will be classified as follows:
1. Mild: The patients are aware of their symptoms and/or signs, but those are tolerable.
They do not require medical intervention or specific treatment.
2. Moderate: Patients present troubles that interfere with their daily activities. They
require medical intervention or specific treatment.
3. Severe: The patients are unable to work or to attend their daily activities. They
require medical intervention or specific treatment.
The possible relationship between the adverse events and the tested medication will be
classified by the investigator on the basis of his/her clinical judgment and the following
definitions:
1. Definitely related: Event can be fully explained by the administration of the tested
medication.
2. Probably related: Event is most likely to be explained by the administration of the
tested medication rather than other medications or by the patient's clinical state.
3. Possibly related: Event may be explained by the administration of the tested medication
or other medications or by the patient's clinical state.
4. Not related: Event is most likely to be explained by the patient's clinical state or
other medications, rather than the tested one.
All the events will be reported to the AEC that, depending on their criteria, will decide
for the continuity or the withdrawal of the patient from the study and therefore the
breaking of the code.
Although the project has been designed to minimize the inherent risks, any adverse event
related to the study medications will be carefully evaluated by the AEC and the costs
generated by the required treatment will be covered by the study.
Data analysis phase
This phase will last 6 months. After completing all the data entry to the CFR, the results
will be audited and the detected errors evaluated and corrected by the person in charge. The
information will be entered in two different databases by two different people and the
records will be compared to detect any discrepancy. The original CFR will be used to correct
any mistake in the database.
For the statistical analysis, Stata 8.0 will be used. The descriptive analysis will be
composed of medians and proportions according to the nature of the variables, with its
respective 95% confidence intervals. As a dispersion measurement the standard deviation will
be calculated. The distribution of the variables will be studied using the Shapiro-Wilk
test. To detect any difference between the groups, a T-test or a Wilcoxon test will be
performed according to its distribution. The categorical variables will be compared using
the Chi2 test or the exact Fisher's test. If required, a model of multiple logistic
regressions or a covariance analysis will be done.
Two interim analyses will be performed when 35% and 70% of the calculated sample is
collected, with the objective of determining the differences in effectiveness and safety
between the treatments.
Endpoints
At the end of the study two endpoints will be evaluated:
1. Successful Treatment:
1. Complete reepithelization three months after the beginning of the treatment.
2. Absence of reactivation and affections of the mucous membranes during the 6 months
of the study.
2. Treatment Failure:
1. Incomplete reepithelization three months after the beginning of the treatment.
2. Increase in the size of the ulcer by more than 50% in relation to the last
clinical evaluation
3. Reactivation and/or affections of the mucous membranes during the 6 months of the
study.
Final Report
At the end of the study the results will be evaluated and discussed and a final report
presented to COLCIENCIAS, entity that is sponsoring the project. The relevant results will
be published in both, national and international journals, and presented in congresses and
scientific meetings.
ETHICAL ASPECTS
This study will be conducted in accordance with the Declaration of Helsinki and with the
Colombian legislation as per the Resolution 8430/93 from the Ministry of Health. Prior to
the admission of the patients in the study, the objectives and the methodology will be
explained and the informed consent obtained. The study was approved by the Research Ethic
Committee of the Cardiovascular Foundation of Colombia (Act# 105/January 28/2005). The right
to confidentiality of the patients will be maintained in all the phases of the study.
COMPETING INTERESTS
Non Financial competing interests
The authors of this manuscript declare that they have no competing interests, including
political, personal, religious, ideological, academic, intellectual, or any other competing
interests.
Financial competing interests
We have not received in the past five years reimbursements, fees, funding or salary from any
organization that may in any way gain or lose from the publication of this manuscript,
either now or in the future. We don't hold any stocks or shares in an organization that may
in any way gain or lose financially from the publication of the manuscript, either now or in
the future. We don't hold or are currently applying for any patents relating to the content
of the manuscript. We have not received reimbursements, fees, funding or salary from an
organization that holds or has applied for patents relating to the content of the
manuscript.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double Blind (Subject, Investigator), Primary Purpose: Treatment
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