Proven therapy for DKD is primarily limited to RAAS blockers and SLGT2i. Weight reduction has the potential to become an additional and much needed treatment option. Of all the weight reduction strategies metabolic surgery is suited to be the most effective. Yet no study has of yet compared the effect of metabolic surgery against best medical treatment on the progression of DKD. This pilot trial is designed to be the first determine the efficacy of metabolic surgery in slowing progression of DKD as compared to best medical therapy. The study design will address all the major limitations previously documented, including the major dilemma of estimating versus measuring GFR. Of note, the study's design will allow its sample size to be adjusted upward using an adaptive design if necessary, to achieve statistical significance. It will also inform study design and sample size issues for all future studies in this field. The payoff of establishing metabolic surgery as a new and effective intervention to slow progression to ESRD would be great in terms of reducing patient suffering and societal costs. This will be an open-label, randomized trial involving sixty (60) patients with diabetic kidney disease (DKD) and obesity who will undergo Roux-en-Y gastric bypass (RYGB) in the intervention arm or receive best medical treatment (BMT) in the control arm. The aim of this prospective, open, randomized study is to evaluate the efficacy and safety of RYGB surgery versus best medical treatment on the progression of DKD in patients with type 2 diabetes and obesity.
This will be an open-label, randomized trial involving sixty (60) patients with DKD and obesity who will undergo RYGB (intervention arm) or receive BMT (control arm). Thirty (30) obese patients with DKD will undergo gastric bypass. Patients will also receive standard of care medical therapy for DKD (ACEI or ARB + SGLT2i) and T2DM (metformin, glitazones, incretin therapy - DPP4 inhibitor and GLP-1 analogs - and insulin, if necessary). Other comorbidities, such as hypertension and dyslipidemia, will be treated according to the latest recommendations of the ADA. The surgical procedure will consist of a laparoscopic surgery performed by an experienced surgeon (approximately 6000 bariatric surgeries), who is accredited as surgeon of excellence by the Brazilian Society of Bariatric and Metabolic Surgery and Surgical Review and Surgical Review Corporation program since 2009. Thirty (30) obese patients with DKD will undergo best medical treatment for DKD (ACEI or ARB + SGLT2i) and T2DM (metformin, glitazones, incretin therapy - DPP4 inhibitor and GLP-1 analogs - and insulin, if necessary). Other comorbidities, such as hypertension and dyslipidemia, will be treated according to the latest recommendations of the ADA. Regarding medication therapy: Metformin will be maintained in the postoperative period while fasting glycemia is above 100 mg/dL unless contraindicated. Anti-antihypertensive drugs and medications for dyslipidemia will be maintained in the postoperative period, unless contraindicated. Micronutrient supplementation (vitamins and mineral salts) will be prescribed to all patients undergoing metabolic surgery. Patients allocated to the control group will receive the same supplementation if necessary.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
60
1. Pneumoperitoneum closed with Veress needle 2. Identification of Treitz angle 3. Measurement of biliary loop (50 cm) 4. Bowel transection with linear stapler (white load) 5. Measurement of the alimentary limb (100 cm) 6. Laterolateral Entero-anastomoses (white load) 7. Construction of gastric pouch distant about 3 cm from the esophageal-gastric junction with stomach section in the small curvature. 8. Linear cutting anastomosis (gastrojejunostomy) from about 1 to 1.2 cm 9. Anastomosis integrity evaluation by methylene blue test and/or perioperative air. Expected surgical time: 60 minutes
Patients will also receive standard of care medical therapy for DKD (ACEI or ARB + SGLT2i) and T2DM (metformin, glitazones, incretin therapy - DPP4 inhibitor and GLP-1 analogs - and insulin, if necessary).
Centro especializado em Obesidade e Diabetes do Hospital Alemão Oswaldo Cruz
São Paulo, São Paulo, Brazil
RECRUITINGMean differenceGlomerular filtration rate (GFR)
Mean difference in GFR between BMT and RYGB at the pre-specified time points of 12 and 36 months after randomization
Time frame: At 12 and 36 months after randomization
Change in twenty-four hour urinary albumin/protein excretion
Change in 24h urinary albumin/protein excretion
Time frame: From baseline to 12 and 36 months
Improvements in micro- or macroalbuminuria
Proportion of patients who achieve improvements in micro- or macroalbuminuria from baseline to 12 and 36 months
Time frame: From baseline to 12 and 36 months
Change in CKD stage and CKD prognostic risk
Change in CKD stage and CKD prognostic risk from baseline to month 12 and 36
Time frame: From baseline to 12 and 36 months
Change in GFR, eGFR and 24 hr creatinine clearance
Change in GFR, eGFR and 24 hr creatinine clearance from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Proportion of participants with ≥30%, ≥40%, and ≥50% reduction in GFR measurements
Proportion of participants with ≥30%, ≥40%, and ≥50% reduction in GFR measurements (GFR, eGFR and 24 hr creatinine clearance) from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Decline in eGFR, sustained low eGFR, kidney transplantation, maintenance dialysis, and kidney death
Time to occurrence of sustained % decline in eGFR, sustained low eGFR, kidney transplantation, maintenance dialysis, and kidney death
Time frame: Time to occurrence (from baseline)
Maintenance dialysis, kidney transplantation, kidney death, and GFR < 15 ml/min
Individual and composite endpoints of maintenance dialysis, kidney transplantation, kidney death, and GFR \< 15 ml/min at 12 and 36 months
Time frame: At 12 and 36 months after randomization
Change in body weight
Change in body weight from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in body mass index
Change in body mass index from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in waist circumference
Change in waist circumference from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Medications to maintain optimal diabetes and blood pressure control
Number and dose of medications to maintain optimal diabetes and blood pressure control from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in fasting glucose
Change in fasting glucose from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in HbA1c
Change in HbA1c from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in basal insulin
Change in basal insulin from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in homeostasis model assessment (HOMA) scores
Change in homeostasis model assessment (HOMA) scores from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Remission in type 2 diabetes
Achievement of partial or complete remission in type 2 diabetes by months 12 and 36
Time frame: At 12 and 36 months after randomization
Change in blood pressure
Change in blood pressure from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Hypoglycemic adverse events
Number of patients with confirmed or symptomatic hypoglycemic adverse events from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Changes in total cholesterol, triglycerides, LDL and HDL levels
Changes in total cholesterol, triglycerides, LDL and HDL levels from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Number of participants achieving LDL < 100 mg/dL and HDL > 40mg/dL
Number of participants achieving LDL \< 100 mg/dL and HDL \> 40mg/dL from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Changes in serum calcium and phosphorus,
Changes in serum calcium and phosphorus from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in parathyroid hormone (PTH)
Change in parathyroid hormone (PTH) from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in mineral bone density
Change in mineral bone density from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in quality of life
Change in quality of life measured by SF-36 questionnaire from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Adverse events
Number of patients with adverse events from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Acute kidney injury
Number of episodes of acute kidney injury from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Adverse cardiovascular events (nonfatal stroke, nonfatal MI, cardiovascular death)
Composite of major adverse cardiovascular events (nonfatal stroke, nonfatal MI, cardiovascular death) from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Mortality
Total mortality from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Days hospitalized
Number of days hospitalized from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in urinary volume
Change in urinary volume from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in calcium and oxalate excretion
Change in calcium and oxalate excretion from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
High sensitivity c-reactive protein
Change in high sensitivity c-reactive protein from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in muscle strength
Change in muscle strength using one repetition maximum (1-RM) from baseline to months12 and 36
Time frame: From baseline to 12 and 36 months
Kidney volumes
Change in kidney volumes from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in ventricular mass
Change in left and right ventricular mass from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Change in ejection fraction
Change in left ventricular ejection fraction from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
Costs of care and health care utilization
Costs of care and health care utilization from baseline to months 12 and 36
Time frame: From baseline to 12 and 36 months
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