Sodium Bicarbonate and Mitochondrial Energetics in Persons With CKD

Overview

Skeletal muscle metabolic health is critical for mobility and an underrecognized target of metabolic acidosis in chronic kidney disease. Impaired muscle mitochondrial metabolism underlies poor physical endurance increasing the risk of mobility disability. The proposed project will use precise in vivo tools to study the pathophysiology of poor physical endurance in a clinical trial treating metabolic acidosis among persons living with chronic kidney disease.

Full Title of Study: “Randomized Cross-over Trial of Sodium Bicarbonate on Muscle Mitochondrial Energetics and Physical Endurance in Chronic Kidney Disease and Metabolic Acidosis”

Study Type

  • Study Type: Interventional
  • Study Design
    • Allocation: Randomized
    • Intervention Model: Crossover Assignment
    • Primary Purpose: Prevention
    • Masking: Quadruple (Participant, Care Provider, Investigator, Outcomes Assessor)
  • Study Primary Completion Date: December 31, 2025

Detailed Description

Chronic kidney disease (CKD) is highly prevalent affecting 14% of the U.S. population leading to substantial morbidity and reduced quality of life. Older adults with CKD identify maintenance of functional independence as their top priority. Skeletal muscle health is critical for mobility and an underrecognized target of metabolic acidosis (MA) and protein energy wasting in CKD. Skeletal muscle endurance provides a window into muscle metabolic health and muscle quality. Muscle mitochondrial metabolism is central to muscle and walking endurance providing energy from carbohydrates and fats to power repeated muscle contraction. Investigators showed metabolic acidosis and muscle adiposity as the major determinants of muscle mitochondrial function. Metabolic acidosis (MA) is long believed to be the main mechanism leading to skeletal muscle wasting and peripheral insulin resistance in CKD. Skeletal muscle mitochondrial metabolism is considered a principal determinant of peripheral insulin sensitivity and muscle quality, but little is known of the impact of MA on muscle mitochondrial function. Muscle mitochondrial dysfunction leads to defective lipid metabolism augmenting adiposity and lipotoxic intermediates resulting in insulin resistance, low endurance, and muscle atrophy. Using in vivo 31Phosphorus Magnetic Resonance Spectroscopy (31P MRS) investigators showed that the presence and severity of CKD is strongly associated with impaired muscle mitochondrial capacity to generate ATP translating into poor walking endurance. Investigators also showed MA and muscle adiposity are the major determinants of muscle mitochondrial function. Despite the importance of mitochondrial function to muscle health, it is unknown if treatment of MA benefits muscle mitochondrial function, adiposity or endurance in CKD. The proposed project will use precise, in vivo 31P MRS and gold-standard testing of peripheral insulin sensitivity by hyperinsulinemic euglycemic clamp to probe the pathophysiology of MA and low endurance in a clinical trial of alkali therapy in CKD and MA. We will compare sodium bicarbonate to placebo in a multicenter randomized, cross-over trial design in 80 persons with moderate-severe CKD and MA. First, the efficacy of 4-months of alkali therapy will be tested comparing sodium bicarbonate versus placebo on muscle metabolic health in a randomized crossover trial in MA. Second, we will test the efficacy of 4-months of alkali therapy comparing sodium bicarbonate versus placebo on improving physical endurance in MA. The rationale is that identification of therapeutic targets for low physical endurance will inform the development of pharmacologic interventions. Long term, it is expected that strategies treating MA will improve exercise tolerance enabling effective engagement in lifestyle interventions improving quality of life in CKD.

Interventions

  • Drug: Sodium bicarbonate
    • Sodium bicarbonate will be dosed at 0.8meq per kilogram of ideal body weight daily (1meq is approximately 84mg). We will use the Devine formula to determine ideal body weight. Investigational Drug Services at both UC Davis and Vanderbilt will compound the sodium bicarbonate. Sodium bicarbonate 650 mg tablets will be over-encapsulated and matching placebo capsules will be prepared. Participants will be limited to a maximum of 9 capsules daily (maximum dose = 5850mg of sodium bicarbonate). Capsules will be dispensed to patients in two separate 8-week allotments. The dose will be rounded to the nearest whole capsule and depending on participant preference may be divided into portions taken twice or thrice daily. Given the high probability of interruption in sodium bicarbonate supply and availability, we may need to change brands of sodium bicarbonate intermittently.
  • Drug: placebo
    • The placebo and filler for for sodium bicarbonate capsules will be comprised of microcrystalline cellulose. Capsule appearance for control and sodium bicarbonate will be the same.

Arms, Groups and Cohorts

  • Experimental: Sodium bicarbonate 16 weeks
    • Sodium bicarbonate will be dosed at 0.8meq per kilogram of ideal body weight daily (1meq is approximately 84mg). We will use the Devine formula to determine ideal body weight. Investigational Drug Services at both UC Davis and Vanderbilt will compound the sodium bicarbonate. Sodium bicarbonate 650 mg tablets will be over-encapsulated and matching placebo capsules will be prepared. Participants will be limited to a maximum of 9 capsules daily (maximum dose = 5850mg of sodium bicarbonate). Capsules will be dispensed to patients in two separate 8-week allotments. The dose will be rounded to the nearest whole capsule and depending on participant preference may be divided into portions taken twice or thrice daily. Given the high probability of interruption in sodium bicarbonate supply and availability, we may need to change brands of sodium bicarbonate intermittently.
  • Placebo Comparator: placebo 16 weeks
    • Microcrystalline cellulose

Clinical Trial Outcome Measures

Primary Measures

  • muscle mitochondrial oxidative capacity by 31P MRS
    • Time Frame: 16 weeks
    • We will use 31P MRS to evaluate the concentration of phospho-creatine (PCr) and other phosphate-energy carrier molecules in limb muscles. After one minute of basal resting measurements, patients will be asked to perform two knee extensions every three seconds against a resistance of 30 to 40% of the maximal voluntary contraction. The exercise protocol will last 90 seconds (a total of 60 knee extensions) followed by four minutes of rest. The exercise/rest cycle will be repeated three times. The intensity of the exercise decreases phosphocreatine (PCr) levels with minimal change in muscle pH. Spectra analysis was performed with AMARES from the jMRUI software package. Spectra are used to calculate the relative concentrations of inorganic phosphate (Pi), PCr, and ATP. The recovery of PCr after the exercise was fit with a monoexponential model that calculated the time constant tau (τ) in unit of seconds, which is the time to restore approximately 63% of the recovery response
  • Insulin sensitivity (SI) by insulin clamp
    • Time Frame: 16 weeks
    • Primary endpoint for the hyperinsulinemic euglycemic clamp testing will be insulin sensitivity defined as (glucose disposal rate – concentration of infused glucose)/(insulin concentration at steady state – fasting insulin concentration). Units are mg/min per microunit per milliliter.
  • total work performed on cycle ergometry VO2
    • Time Frame: 16 weeks
    • Total work will be obtained by cycle ergometry using standard protocol measuring oxygen uptake starting at 0 watts (W) at 60 rotations per minute (rpm) increasing by 25W every 2 minutes until volitional exhaustion adapting a prior protocol used in CKD patients. The primary measure will be total work completed (Joules).
  • muscle work efficiency cycle ergometry
    • Time Frame: 16 weeks
    • joules/ml Oxygen(VO2 peak)
  • Walking endurance by 6-minute walk
    • Time Frame: 16 weeks
    • Meters
  • FACIT-F Fatigue (PRO)
    • Time Frame: 16 weeks
    • score on FACIT-F questionnaire

Secondary Measures

  • Intermuscular fat by MRI
    • Time Frame: 16 weeks
    • Percent intermuscular fat.
  • 30 second sit to stand test
    • Time Frame: 16 weeks
    • number of times patient can get up from sitting position over 30 seconds
  • PROMIS Fatigue (PRO)
    • Time Frame: 16 weeks
    • score on NIH PROMIS Fatigue questionnaire

Participating in This Clinical Trial

Inclusion Criteria

  • Moderate-severe CKD determined by eGFR <50ml/min per 1.73m2 by CKD EPI equation on at least 2 consecutive occasions. – Metabolic acidosis defined as bicarbonate level<24 on two consecutive occasions. – Age 21 to 85 years old Exclusion Criteria:

  • Type 2 diabetes managed with insulin treatment – Poorly controlled diabetes (HgbA1c>10%) – History of persistent hyperkalemia (K>5.4) – Chronic treatment with renal replacement therapy – History of aortic dissection or severe valvular heart disease – Exercise induced angina – Uncontrolled cardiac dysrhythmia – Oxygen dependent COPD – Symptomatic claudication – End stage liver disease – Mobility disability defined as inability to walk without human assistance – Dementia or psychosis – Patients who cannot consent – Active use of IV drugs – Non-english speaking – History of transplant – Implants that prohibit MRI measurements or trauma involving metal fragments – Pacemaker – Expectation to start dialysis during the course of study. – Any condition which in the judgement of the clinical investigator places the participant at risk from participation in the study.

Gender Eligibility: All

Minimum Age: 21 Years

Maximum Age: 85 Years

Are Healthy Volunteers Accepted: No

Investigator Details

  • Lead Sponsor
    • University of California, Davis
  • Collaborator
    • Vanderbilt University Medical Center
  • Provider of Information About this Clinical Study
    • Principal Investigator: Baback Roshanravan, Associate Professor, Nephrology – University of California, Davis
  • Overall Official(s)
    • Baback Roshanravan, MD, Principal Investigator, UC Davis
    • Jorge Gamboa, MD PhD, Principal Investigator, Vanderbilt University
  • Overall Contact(s)
    • Baback Roshanravan, MD, 530-754-0893, broshanr@ucdavis.edu

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