Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT05334979 |
| Other study ID # |
IRB21-1349 |
| Secondary ID |
|
| Status |
Recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
October 27, 2022 |
| Est. completion date |
July 1, 2025 |
Study information
| Verified date |
April 2024 |
| Source |
University of Chicago |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
This is a single-center study that aims to earn more about how two different compounds found
in food, oxalate and citrate, may affect a person's chances of forming kidney stones.
Description:
Experimental Design and Implications Administration of oral oxalate without citrate will
determine the contribution of diet to this association. We will measure fractional excretion
of oxalate and citrate. Both are freely filtered by the glomerulus and either secreted or
reabsorbed (oxalate) or just reabsorbed (citrate). We will be able to assess urine excretions
partitioned from the contribution of the filtered load and subsequent tubule handling by
using fractional excretion.
This study has large implications for both patient care and future studies. If the urine
oxalate-citrate association is primarily related to dietary oxalate and citrate, then
fractional excretion of citrate will not increase after our proposed isolated dietary oxalate
load test in controls or stone formers. This observation will allow practitioners to consider
this when developing diets for kidney stone prevention and consider recommending consuming
foods high in citrate (or supplementing alkali) simultaneous with oxalate consumption. In
addition, the results of this experiment will lead to future studies including alkali
supplementation prior to the oxalate load test to see if urine oxalate-citrate balance can be
restored. If the oxalate-citrate association is not solely driven by diet, we anticipate a
rise in fractional excretion of citrate and a difference in the urinary oxalate-citrate
relationship between non-stone formers and stone formers. If so, this association may be
related to SLC26Ac/NaDC-1 gene linkage and its potential disruption in stone formers. This
may lead to future genetic and drug studies related to regulation of these transporters.
Finally, differences in urinary oxalate-citrate association between non-stone-formers and
stone formers may be a related to disordered acid-base handling that contributes to the
blunted association in stone formers and further observed in those with Roux-en-Y Gastric
Bypass. Much of the work on disordered acid-base handling in stone formers has been done by
Drs. Worcester and Coe. Therefore, a future study providing supplemental alkali with oxalate
containing foods may provide additional insight into stone risk mechanisms for these
patients.
APPROACH Experimental Design: Studies will be carried out in the University of Chicago
Medicine (UCM) Clinical Research Center (CRC).
Informed Consent Process: Subjects will be taken through the informed consent process by
myself or the study research assistant. Subjects will be given ample time to discuss and ask
questions. No study activities will occur until after the subject has signed the consent
form.
In non-stone-formers (N=25) and non-obese calcium/oxalate stone-formers(N=25), give an oral
(360mg) sodium oxalate load and measure both urine and serum oxalate and citrate over six
hours. Primary endpoint (hypothesis 1a) is change from baseline in fractional excretion of
citrate adjusted for change in fractional excretion oxalate after oxalate load. Secondary
endpoint (hypothesis 1b) is to compare change in fractional excretion of citrate adjusted to
fractional excretion oxalate in non-obese stone-formers versus non-stone-formers.
Rationale: There is an association between urine oxalate and citrate excretion which is
greater in non-stone-formers than in stone formers. If this is due to a specific effect of
oxalate transport in the proximal tubule on citrate reabsorption, then administration of an
oral oxalate load should lead to increased urine citrate excretion, and this increase may
differ between non-stone-formers and stone formers. Therefore, 1a: an oral sodium oxalate
load will increase fractional excretion of citrate; and 1b: will raise fractional excretion
of citrate more in non-stone-formers than in non-obese stone formers. If true, this suggests
a link at the level of proximal tubule transporter (SLC26A6/NaDC1) function. If false, other
mechanisms such as dietary variation, must be responsible
Study Population and Recruitment: Enroll a total of 50 subjects (25 non-stone-formers, 25
stone formers) with equal numbers by sex over the first two years or the award.
non-stone-formers controls will be recruited using Research Match and The New Normal research
participant resources of the UCM Institute for Translational Medicine. Research Match and The
New Normal are resources for finding individuals who are interested in participating in
research studies. Queries can be used to identify eligible controls. Eligible
non-stone-forming controls will complete one home 24-hour baseline urine collection at home
to screen for any severe acid-base or oxalate abnormalities. Stone-forming participants (all
of whom have 24-hour data available) will be recruited from the UCM Kidney Stone Clinic (both
current and repository of previous patients). The UCM Kidney Stone Clinic is a large clinic
with over 50 years of patients. Our group has a long history of successfully recruiting
research participants from this source.
Protocol: This protocol was developed and adapted based on previously published
methodologies.40-42 We will select stone-forming patients both on and not on alkali
supplementation. Those on alkali supplementation will be asked to discontinue for two weeks
prior to study day. For all patients, one week prior to study day, all vitamin C,
multivitamins, calcium supplements, and diuretics will be held. Holding of diuretics and
alkali supplementation will be done in discussion with patient's primary nephrologist or
primary care physician to discuss safety in stopping these medications for the study period.
One day prior to study day, participants will complete 24-hour urine collection and food
frequency questionnaire at home. On study day, participants will be admitted to the CRC in a
fasting state. Baseline (time 0) urine and blood specimens will be collected and height and
weight will be measured. Participant will consume a 360mg (4mmol) oral sodium oxalate load
dissolved in 250ml of distilled water. This content of oxalate was selected based on previous
studies that support this level as adequate to observe a signal of urine oxalate.43 This
content of oxalate is safe for patients and below the range of a typical portion of spinach
(>700mg/100g). Repeat timed urine (every 1 hour) and blood specimens (every 2 hours) will be
obtained for 6 hours after the oral oxalate load. Blood collections will be approximately 8ml
blood per draw (total of 4 blood draws). Participants will receive a low oxalate and citrate
study breakfast but consume no other food until study completion. Water intake will be
allowed ad lib.
Urine and Serum Measurements: 24-hour and timed urine collections will be completed.
Instructions for home 24-hour urine collections will be provided. Urine will be collected
under oil so that all acid-base parameters can be measured, including a total carbon dioxide
(CO2). Urine will be assayed for oxalate and citrate as well as other kidney stone risk
factor chemistries including urine volume, calcium, pH, uric acid, sodium, potassium,
chloride, magnesium, phosphorus, urea, sulfate, ammonium, and creatinine. Supersaturation of
calcium oxalate, calcium phosphate, and uric acid will be calculated using EQUIL2 (a computer
program used to estimate the risk of renal stones). These additional assays will provide data
for future study. Serum sodium, potassium, chloride, bicarbonate, calcium, phosphorus,
magnesium, creatinine, and ultrafilterable (UF) calcium, citrate, and oxalate will be
measured. All urine and serum measurements will be performed at the UCM Kidney Stone
Laboratory except UF oxalate which will be measured at University of Alabama-Birmingham
(UAB). Serum and urine will be frozen at -80° C and stored for potential later assays.
Clinical variable collection: Clinical variables will include age, sex, height, weight, body
mass index, chronic medical conditions, and medications. Clinical variables will be collected
from the electronic health record and verified in interview by me or the research assistant.
Statistical Analysis: Change in urine oxalate, urine citrate, and fractional excretions of
citrate and oxalate from baseline (time 0) to 2-, 4-, and 6-hour time points will be
calculated for each participant. Descriptive statistics and t-tests will be used to
demonstrate the change in urine citrate and fractional excretion of citrate by change in
oxalate at each time period for all participants and between stone-formers and
non-stone-formers. The levels of urine oxalate and citrate and fractional excretions of
citrate and oxalate will be graphed over time. Longitudinal methods will be used to perform
regression modeling of the association of urine citrate by urine oxalate for all patients and
stratified by stone-formers' status. Variables to be considered for multivariate analysis
include clinical (sex, body mass index) and urinary (GI anion) variables.
