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Diabetic nephropathy

April 11, 2024

Diabetic nephropathy, also known as diabetic kidney disease,[5] is the chronic loss of kidney function occurring in those with diabetes mellitus. Diabetic nephropathy is the leading causes of chronic kidney disease (CKD) and end-stage renal disease (ESRD) globally. The triad of protein leaking into the urine (proteinuria or albuminuria), rising blood pressure with hypertension and then falling renal function is common to many forms of CKD. Protein loss in the urine due to damage of the glomeruli may become massive, and cause a low serum albumin with resulting generalized body swelling (edema) so called nephrotic syndrome. Likewise, the estimated glomerular filtration rate (eGFR) may progressively fall from a normal of over 90 ml/min/1.73m2 to less than 15, at which point the patient is said to have end-stage renal disease.[6] It usually is slowly progressive over years.[7]

Diabetic nephropathy
Other namesDiabetic kidney disease
Two glomeruli in diabetic nephropathy: the acellular light purple areas within the capillary tufts are the destructive mesangial matrix deposits.
SpecialtyNephrology, endocrinology 
SymptomsAlbuminuria,[1] peripheral edema,[1] high blood pressure,[1] tiredness[2]
Risk factorsHigh blood pressure, tobacco smoking,[1] unstable blood glucose[2]
Diagnostic methodAbnormal levels of urinary albumin[3]
PreventionSmoking cessation[1]
TreatmentACE inhibitors[4]

Pathophysiologic abnormalities in diabetic nephropathy usually begin with long-standing poorly controlled blood glucose levels. This is followed by multiple changes in the filtration units of the kidneys, the nephrons. (There are normally about 750,000–1.5 million nephrons in each adult kidney).[8] Initially, there is constriction of the efferent arterioles and dilation of afferent arterioles, with resulting glomerular capillary hypertension and hyperfiltration particularly as nephrons become obsolescent and the adaption of hyperfiltration paradoxically causes further shear stress related damage to the delicate glomerular capillaries, further proteinuria, rising blood pressure and a vicious circle of additional nephron damage and decline in overall renal function.[9][10] Concurrently, there are changes within the glomerulus itself: these include a thickening of the basement membrane, a widening of the slit membranes of the podocytes, an increase in the number of mesangial cells, and an increase in mesangial matrix. This matrix invades the glomerular capillaries and produces deposits called Kimmelstiel-Wilson nodules. The mesangial cells and matrix can progressively expand and consume the entire glomerulus, shutting off filtration.[11]

The status of diabetic nephropathy may be monitored by measuring two values: the amount of protein in the urine - proteinuria; and a blood test called the serum creatinine. The amount of the proteinuria reflects the degree of damage to any still-functioning glomeruli. The value of the serum creatinine can be used to calculate the estimated glomerular filtration rate (eGFR), which reflects the percentage of glomeruli which are no longer filtering the blood. [citation needed] Treatment with an angiotensin converting enzyme inhibitor or angiotensin receptor blocker, which dilates the arteriole exiting the glomerulus, thus reducing the blood pressure within the glomerular capillaries, may slow (but not stop) progression of the disease. Three classes of diabetes medications – GLP-1 agonists, DPP-4 inhibitors, and SGLT2 inhibitors– are also thought to slow the progression of diabetic nephropathy.[12]

Diabetic nephropathy is the most common cause of end-stage renal disease and is a serious complication that affects approximately one quarter of adults with diabetes in the United States.[13][14] Affected individuals with end-stage kidney disease often require hemodialysis and eventually kidney transplantation to replace the failed kidney function.[15] Diabetic nephropathy is associated with an increased risk of death in general, particularly from cardiovascular disease.[13][16]

Signs and symptoms edit

The onset of symptoms is 5 to 10 years after the disease begins.[2] A usual first symptom is frequent urination at night: nocturia. Other symptoms include tiredness, headaches, a general feeling of illness, nausea, vomiting, frequent daytime urination, lack of appetite, itchy skin, and leg swelling.[2] The clinical presentation of diabetic nephropathy (DN) is characterized by proteinuria (protein in the urine), hypertension and progressive loss of kidney function. The process may be initially indolent, making regular screening for diabetic nephropathy in patients with diabetes mellitus of great importance.[17]

Risk factors edit

Not all patients with diabetes go on to develop diabetic nephropathy. The main risk factors that increase the likelihood of developing diabetic nephropathy are:[2]

  • Poor control of blood glucose
  • Uncontrolled high blood pressure
  • Type 1 diabetes mellitus, with onset before age 20
  • Past or current cigarette use[18]
  • A family history of diabetic nephropathy- certain genes have been identified that are associated with DN. ( However, no direct correlation has been established yet.[19] One of these genes is APOL1, which has been found to be associated with nephropathy in African American individuals.[20])
  • Certain racial groups (African Americans, Mexican Americans, and Pima Indians are at higher risk).

Pathophysiology edit

 
Diagram showing the basic outline of nephron structure and function: diabetic nephropathy is associated with changes in the afferent and efferent arterioles, causing capillary hypertension; and damage to the glomerular capillaries of multiple causes, including mesangial matrix deposition
See also: Review of normal Renal Physiology

The disease progression of diabetic nephropathy involves various clinical stages: hyperfiltration, microalbuminuria, macroalbuminuria, nephrotic proteinuria to progressive chronic kidney disease leading to end-stage renal disease (ESRD). The damage is exerted on all compartments of the kidney: the glomerulus, the renal tubules, the vasculature (afferent and efferent renal arterioles) and the interstitium. Renal fibrosis is the final common pathway of DN. This fibrosis is a product of multiple mechanisms including renal hemodynamic changes, glucose metabolism abnormalities associated with oxidative stress as well as inflammatory processes and an overactive renin-angiotensin-aldosterone system (RAAS).[citation needed]

The pathophysiology of diabetic nephropathy is thought to involve an interaction between hemodynamic and metabolic factors.[21]

Hemodynamic factors include an increase in systemic and intraglomerular pressure, as well as the over-activation of the RAAS. Studies have shown that in the setting of diabetes, various factors stimulate the RAAS, which is one of the most important pathways in diabetic nephropathy pathophysiology. Due to the higher load of filtered glucose, there is an up-regulation in the sodium-glucose cotransporter 2 (SGLT2) in the proximal tubules, which cotransports sodium and glucose back into circulation. This leads to a decrease in the delivery of sodium chloride to the macula densa in the distal tubules, promoting the release of renin and over-activating RAAS.[22] Hyperfiltration is one of the earliest features of DN. Several mechanisms have been proposed to cause hyperfiltration. One of these mechanisms is that as glomeruli becomes hypertrophied, filtration surface area initially increases. Another possible mechanism is that abnormal vascular control in diabetic nephropathy leads to a reduction in afferent glomerular arteriolar resistance and an increase in efferent glomerular arteriolar resistance, leading to a net increase in renal blood flow (RBF) and glomerular filtration rate (GFR).[23] Glomerular hyperfiltration and an aberrant regulation of RAAS lead to increased intraglomerular pressure, causing stress on the endothelial cells, the mesangial cells and the podocytes. This exacerbates the dysfunction caused by the metabolic effects of hyperglycemia.[citation needed]

Metabolic factors include the formation of advanced glycation end-products (AGEs), which have a central role in the pathophysiology of many of the complications of diabetes mellitus, including cardiovascular complications.[24] AGEs are chemical groups that form when a reducing sugar (glucose in this case) reacts non-enzymatically with an amine group, predominantly lysine and arginine, which are attached on proteins, lipids and nucleic acids.[25] These glycation products accumulate on the proteins of vessel wall collagen, forming an irreversible complex of cross-linked AGEs. An important way AGEs exert their effect is through a receptor-mediated mechanism, most importantly by the receptor for advanced glycation end products (RAGE). RAGE is a signal transduction receptor found on a number of cell types including macrophages, endothelial cells, renal mesangial cells and podocytes in the glomerulus.[26] Bindings of AGEs to RAGE receptors enhances production of cytosolic Reactive Oxygen Species (ROS) as well as stimulates intracellular molecules such as Protein Kinase C (PKC), NF-κB and the activation of growth factors TGF-B and vascular endothelial growth factor (VEGF). These factors, along with the hemodynamic changes that occur, lead to podocyte injury, oxidative stress, inflammation and fibrosis. As injury worsens, kidney function decreases and glomerular basement membrane (GBM) become more permeable and less efficient at filtration. This is accompanied by a steady decline in kidney function.[citation needed]

Diagnosis edit

 
Ultrasonography showing hyperechogenicity of the renal cortex, visualized in the image as brighter than the liver.

Diagnosis is based on the measurement of abnormal levels of urinary albumin in a diabetic[27] coupled with exclusion of other causes of albuminuria. Albumin measurements are defined as follows:[28]

Urinary albumin excretion can also be measured by urinary albumin/creatinine ratio in a spot urine sample, which is as accurate but more convenient than a 24-hour urine collection.[29]

It is recommended that diabetics have their albumin levels checked annually, beginning immediately after a diagnosis of type 2 diabetes and five years after a diagnosis of type 1 diabetes.[27][30] Medical imaging of the kidneys, generally by ultrasonography, is recommended as part of a differential diagnosis if there is suspicion of urinary tract obstruction, urinary tract infection, kidney stones or polycystic kidney disease.[31] Conformation kidney biopsy should only be performed if non-diabetic kidney disease is suspected.[citation needed]

Urine analysis in patients with diabetic kidney disease is often bland. In cases of severely increased microalbuminuria, hematuria might be present.[32] fat bodies might be present in patients who develop nephrotic-range proteinuria.

Clinical staging[33]
CKD
Stage 		eGFR level
(mL/min/1.73 m2)
Stage 1 ≥ 90
Stage 2 60–89
Stage 3 30–59
Stage 4 15–29
Stage 5 < 15

Staging edit

To clinically stage the degree of damage in this (and any) kidney disease, the serum creatinine is determined and used to calculate the estimated glomerular filtration rate (eGFR). Normal eGFR is equal to or greater than 90ml/min/1.73 m2.[34] On biopsy, the following classification has been suggested by Tervaert et al.:[35]

Histopathologic staging
Class Description and criteria
I Mild or nonspecific changes on light microscopy and conformed GBM
thickening proven by electron microscopy: GBM > 395 nm (female), GBM > 430 nm (male).
IIa
  • Mild mesangial expansion in >25% of the observed mesangium.
  • Area of mesangial proliferation < area of capillary cavity.
IIb
  • Severe mesangial expansion in >25% of the observed mesangium.
  • Area of mesangial proliferation < area of capillary cavity.
III At least one convincing nodular sclerosis (Kimmelstiel-Wilson lesion).
IV Advanced diabetic glomerulosclerosis in >50% of glomeruli.

Biomarkers edit

Although albuminuria is the most frequently used marker of DN, it has a limited sensitivity as many patients with diabetic nephropathy experience GFR loss and glomerulosclerosis without immediate elevation in albuminuria. Many novel markers are currently being studied that potentially detect diabetic nephropathy at earlier stages and identify progression risk. Cystatin C is a protein that is freely filtered in the glomeruli before it is reabsorbed and catabolized in the renal tubular cells. Its serum level is independent of muscle mass, making more accurate at estimating GFR than creatinine serum levels.[citation needed]

Treatment edit

The goals of treatment are to slow the progression of kidney damage and control related complications. Management of diabetic nephropathy currently centers over four main areas: Cardiovascular risk reduction, glycemic control, blood pressure control as well as inhibition of the RAAS system.[citation needed]

Cardiovascular risk reduction: Patients with diabetes mellitus are at significantly increased risk of cardiovascular disease, which is also an independent risk factor for kidney failure. Therefore, it is important to aggressively manage cardiovascular risk factors in patients with diabetes mellitus and in particular those with diabetic nephropathy. The main components of managing cardiovascular disease is with tobacco cessation, lipid-lowering therapies (e.g., statins) as well as regular exercise and healthy eating.[36] In patients with kidney disease, atorvastatin is preferred over other statins as it does not require dose-adjustment based on GFR.[37]

Glycemic control: Multiple studies have found a positive effect of improved glycemic control on clinical outcomes of patients with diabetic nephropathy.[38] Intensive glycemic control also reduces the rate of other DM complications, such as retinopathy and neuropathy. Glycemic control is maintained mainly with insulin in patients with Type 1 DM and with hypoglycemic agents and/or insulin in patients with type 2 DM. Studies showed a decrease in microvascular complications of diabetic nephropathy with a target goal HbA1c concentration of 7%. Further reduction in the HbA1c did not correlate with better outcomes and is thus not recommended in most patients as it could increase the risk of hypoglycemic episodes.[39][40]

Blood pressure control: Multiple randomized clinical trials have demonstrated a benefit of decreasing systolic blood pressure to <140 mmHg in patients with diabetic nephropathy. High blood pressure is associated with accelerated development of microalbuminuria, over proteinuria and declining kidney function. Angiotensin-converting-enzyme inhibitors, as well as angiotensin II receptor blockers, are particularly helpful in patients with diabetes to lower blood pressure and slow the progression of nephropathy.[41] More intensive blood pressure lower (125-130/<80) in patients with diabetic mellitus has been shown to decrease the risk of progression of diabetic nephropathy as well as other diabetic complications.[42] Some patients might require dual therapy to adequately control pressure, in which case calcium channel blockers or diuretics are a good second-line option.[43]

RAAS inhibition: Inhibition can be achieved with multiple therapies, mainly ACE inhibitors, angiotensin receptor blockers, direct renin inhibitors, and mineralocorticoid antagonists. RAAS inhibition has been proven to be the most effective therapy to slow the progression of diabetic nephropathy in all stages.[44] Although RAAS blockade using more than one agent may further reduce proteinuria, the risk of adverse events (such as hyperkalemia, acute kidney injury) outweigh the potential benefits.[45] Therefore, it is recommended that only one agent is used in patients with DM who have hypertension or any signs of microalbuminuria or diabetic nephropathy.[46]

About half of insulin is metabolized and cleared by the kidneys. This means that as kidney function worsens in the setting of DN, some patients with insulin-dependent DM may find that their regular insulin doses are lasting longer than normal, or that they are experiencing an increasing frequency of hypoglycemic episodes. It is also crucial to closely monitor kidney function to properly dose medications that are cleared by the kidneys. Some of the most commonly used nephrotoxic medications are non-steroidal anti-inflammatory drugs (NSAIDs) such as ibuprofen.[47] With worsening kidney function, it might also be necessary to follow a renal-diet to avoid complications such as hyperkalemia and metabolic acidosis. Some evidence suggests that limiting dietary protein could slow the progression of DN, but further evidence is needed to confirm this benefit.[48] Patients with diabetic nephropathy might go on to develop end stage renal disease and require kidney transplantation or hemodialysis.[citation needed]

Emerging therapies edit

A relatively new medication that has been approved for treatment for DM is sodium glucose cotransporter 2 (SGLT2) inhibitors. The mechanism of action of this drug is to the sodium-glucose uptake cotransporter in the proximal tubule, thereby generating naturesis and glucosuria. In multiple clinical trials, SGLT2 inhibitors showed improved cardiovascular outcomes in patients with DM as well a positive effect on kidney outcomes, mainly a reduction in albuminuria and progression of renal damage.[49][50] Other classes of diabetic medications that have been shown to have a positive effect on the progression of diabetic nephropathy are GLP-1 agonists and DPP-4 inhibitors.[citation needed]

Education and self-management edit

The success of diabetic nephropathy management depends greatly upon the ability of individuals to self-manage this condition, encompassing glycaemic control, and the adoption of healthy lifestyles. Appropriate self-management often requires patient education and behavioural counselling. However, there is still insufficient evidence to draw conclusions regarding the effects, regarding both benefits and harms, of educational programmes for people with diabetic nephropathy.[51] Further high-quality studies are warranted.

Prognosis edit

Diabetic nephropathy in type 2 diabetes can be more difficult to predict because the onset of diabetes is not usually well established. Without intervention, 20–40 percent of patients with type 2 diabetes/microalbuminuria, will evolve to macroalbuminuria.[52] Diabetic nephropathy is the most common cause of end-stage kidney disease,[13][14] which may require hemodialysis or even kidney transplantation.[15] It is associated with an increased risk of death in general, particularly from cardiovascular disease.[13][16]

Epidemiology edit

Diabetic nephropathy affects approximately a third of patients with type 1 and type 2 diabetes mellitus. Diabetic nephropathy is responsible for about a third of cases of ESRD worldwide, and an even larger fraction in the developed countries.[53] Worldwide, the prevalence of diabetes is projected to increase from 382 million in 2013, to over 592 million by 2035. This increase is projected to be sharpest in developed countries. The prevalence of type 2 DM is particularly increasing due to the rising prevalence of obesity worldwide.[54] Diabetic kidney disease progression could lead to ESRD as well as an increased risk of cardiovascular complications, all of which cause a substantial economic burden. The estimated cost of management of patients with ESRD due to diabetic nephropathy in the US is US$39.35 billion in 2010.[55] Within developed countries, certain ethnic groups such as African Americans and Native Americans are at higher risk of developing diabetic nephropathy and ESRD.[56]

See also edit

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Further reading edit

  • "Effects of renin-angiotensin system blockers on renal outcomes and all-cause mortality in patients with diabetic nephropathy: an updated meta-analysis". www.crd.york.ac.uk. Retrieved 2015-07-02.
  • Gross JL, de Azevedo MJ, Silveiro SP, Canani LH, Caramori ML, Zelmanovitz T (January 2005). "Diabetic nephropathy: diagnosis, prevention, and treatment". Diabetes Care. 28 (1): 164–76. doi:10.2337/diacare.28.1.164. PMID 15616252.
  • Tziomalos K, Athyros VG (2015). "Diabetic Nephropathy: New Risk Factors and Improvements in Diagnosis". The Review of Diabetic Studies. 12 (1–2): 110–8. doi:10.1900/RDS.2015.12.110. PMC 5397986. PMID 26676664.
  • Kume S, Koya D, Uzu T, Maegawa H (2014). "Role of nutrient-sensing signals in the pathogenesis of diabetic nephropathy". BioMed Research International. 2014: 315494. doi:10.1155/2014/315494. PMC 4122096. PMID 25126552.
  • Doshi SM, Friedman AN (August 2017). "Diagnosis and Management of Type 2 Diabetic Kidney Disease". Clinical Journal of the American Society of Nephrology. 12 (8): 1366–1373. doi:10.2215/CJN.11111016. PMC 5544517. PMID 28280116.

External links edit

 
Scholia has a topic profile for Diabetic nephropathy.

April 11, 2024
diabetic, nephropathy, also, known, diabetic, kidney, disease, chronic, loss, kidney, function, occurring, those, with, diabetes, mellitus, leading, causes, chronic, kidney, disease, stage, renal, disease, esrd, globally, triad, protein, leaking, into, urine, . Diabetic nephropathy also known as diabetic kidney disease 5 is the chronic loss of kidney function occurring in those with diabetes mellitus Diabetic nephropathy is the leading causes of chronic kidney disease CKD and end stage renal disease ESRD globally The triad of protein leaking into the urine proteinuria or albuminuria rising blood pressure with hypertension and then falling renal function is common to many forms of CKD Protein loss in the urine due to damage of the glomeruli may become massive and cause a low serum albumin with resulting generalized body swelling edema so called nephrotic syndrome Likewise the estimated glomerular filtration rate eGFR may progressively fall from a normal of over 90 ml min 1 73m2 to less than 15 at which point the patient is said to have end stage renal disease 6 It usually is slowly progressive over years 7 Diabetic nephropathyOther namesDiabetic kidney diseaseTwo glomeruli in diabetic nephropathy the acellular light purple areas within the capillary tufts are the destructive mesangial matrix deposits SpecialtyNephrology endocrinology SymptomsAlbuminuria 1 peripheral edema 1 high blood pressure 1 tiredness 2 Risk factorsHigh blood pressure tobacco smoking 1 unstable blood glucose 2 Diagnostic methodAbnormal levels of urinary albumin 3 PreventionSmoking cessation 1 TreatmentACE inhibitors 4 Pathophysiologic abnormalities in diabetic nephropathy usually begin with long standing poorly controlled blood glucose levels This is followed by multiple changes in the filtration units of the kidneys the nephrons There are normally about 750 000 1 5 million nephrons in each adult kidney 8 Initially there is constriction of the efferent arterioles and dilation of afferent arterioles with resulting glomerular capillary hypertension and hyperfiltration particularly as nephrons become obsolescent and the adaption of hyperfiltration paradoxically causes further shear stress related damage to the delicate glomerular capillaries further proteinuria rising blood pressure and a vicious circle of additional nephron damage and decline in overall renal function 9 10 Concurrently there are changes within the glomerulus itself these include a thickening of the basement membrane a widening of the slit membranes of the podocytes an increase in the number of mesangial cells and an increase in mesangial matrix This matrix invades the glomerular capillaries and produces deposits called Kimmelstiel Wilson nodules The mesangial cells and matrix can progressively expand and consume the entire glomerulus shutting off filtration 11 The status of diabetic nephropathy may be monitored by measuring two values the amount of protein in the urine proteinuria and a blood test called the serum creatinine The amount of the proteinuria reflects the degree of damage to any still functioning glomeruli The value of the serum creatinine can be used to calculate the estimated glomerular filtration rate eGFR which reflects the percentage of glomeruli which are no longer filtering the blood citation needed Treatment with an angiotensin converting enzyme inhibitor or angiotensin receptor blocker which dilates the arteriole exiting the glomerulus thus reducing the blood pressure within the glomerular capillaries may slow but not stop progression of the disease Three classes of diabetes medications GLP 1 agonists DPP 4 inhibitors and SGLT2 inhibitors are also thought to slow the progression of diabetic nephropathy 12 Diabetic nephropathy is the most common cause of end stage renal disease and is a serious complication that affects approximately one quarter of adults with diabetes in the United States 13 14 Affected individuals with end stage kidney disease often require hemodialysis and eventually kidney transplantation to replace the failed kidney function 15 Diabetic nephropathy is associated with an increased risk of death in general particularly from cardiovascular disease 13 16 Contents 1 Signs and symptoms 2 Risk factors 3 Pathophysiology 4 Diagnosis 4 1 Staging 4 2 Biomarkers 5 Treatment 5 1 Emerging therapies 5 2 Education and self management 6 Prognosis 7 Epidemiology 8 See also 9 References 10 Further reading 11 External linksSigns and symptoms editThe onset of symptoms is 5 to 10 years after the disease begins 2 A usual first symptom is frequent urination at night nocturia Other symptoms include tiredness headaches a general feeling of illness nausea vomiting frequent daytime urination lack of appetite itchy skin and leg swelling 2 The clinical presentation of diabetic nephropathy DN is characterized by proteinuria protein in the urine hypertension and progressive loss of kidney function The process may be initially indolent making regular screening for diabetic nephropathy in patients with diabetes mellitus of great importance 17 Risk factors editNot all patients with diabetes go on to develop diabetic nephropathy The main risk factors that increase the likelihood of developing diabetic nephropathy are 2 Poor control of blood glucose Uncontrolled high blood pressure Type 1 diabetes mellitus with onset before age 20 Past or current cigarette use 18 A family history of diabetic nephropathy certain genes have been identified that are associated with DN However no direct correlation has been established yet 19 One of these genes is APOL1 which has been found to be associated with nephropathy in African American individuals 20 Certain racial groups African Americans Mexican Americans and Pima Indians are at higher risk Pathophysiology edit nbsp Diagram showing the basic outline of nephron structure and function diabetic nephropathy is associated with changes in the afferent and efferent arterioles causing capillary hypertension and damage to the glomerular capillaries of multiple causes including mesangial matrix depositionSee also Review of normal Renal Physiology The disease progression of diabetic nephropathy involves various clinical stages hyperfiltration microalbuminuria macroalbuminuria nephrotic proteinuria to progressive chronic kidney disease leading to end stage renal disease ESRD The damage is exerted on all compartments of the kidney the glomerulus the renal tubules the vasculature afferent and efferent renal arterioles and the interstitium Renal fibrosis is the final common pathway of DN This fibrosis is a product of multiple mechanisms including renal hemodynamic changes glucose metabolism abnormalities associated with oxidative stress as well as inflammatory processes and an overactive renin angiotensin aldosterone system RAAS citation needed The pathophysiology of diabetic nephropathy is thought to involve an interaction between hemodynamic and metabolic factors 21 Hemodynamic factors include an increase in systemic and intraglomerular pressure as well as the over activation of the RAAS Studies have shown that in the setting of diabetes various factors stimulate the RAAS which is one of the most important pathways in diabetic nephropathy pathophysiology Due to the higher load of filtered glucose there is an up regulation in the sodium glucose cotransporter 2 SGLT2 in the proximal tubules which cotransports sodium and glucose back into circulation This leads to a decrease in the delivery of sodium chloride to the macula densa in the distal tubules promoting the release of renin and over activating RAAS 22 Hyperfiltration is one of the earliest features of DN Several mechanisms have been proposed to cause hyperfiltration One of these mechanisms is that as glomeruli becomes hypertrophied filtration surface area initially increases Another possible mechanism is that abnormal vascular control in diabetic nephropathy leads to a reduction in afferent glomerular arteriolar resistance and an increase in efferent glomerular arteriolar resistance leading to a net increase in renal blood flow RBF and glomerular filtration rate GFR 23 Glomerular hyperfiltration and an aberrant regulation of RAAS lead to increased intraglomerular pressure causing stress on the endothelial cells the mesangial cells and the podocytes This exacerbates the dysfunction caused by the metabolic effects of hyperglycemia citation needed Metabolic factors include the formation of advanced glycation end products AGEs which have a central role in the pathophysiology of many of the complications of diabetes mellitus including cardiovascular complications 24 AGEs are chemical groups that form when a reducing sugar glucose in this case reacts non enzymatically with an amine group predominantly lysine and arginine which are attached on proteins lipids and nucleic acids 25 These glycation products accumulate on the proteins of vessel wall collagen forming an irreversible complex of cross linked AGEs An important way AGEs exert their effect is through a receptor mediated mechanism most importantly by the receptor for advanced glycation end products RAGE RAGE is a signal transduction receptor found on a number of cell types including macrophages endothelial cells renal mesangial cells and podocytes in the glomerulus 26 Bindings of AGEs to RAGE receptors enhances production of cytosolic Reactive Oxygen Species ROS as well as stimulates intracellular molecules such as Protein Kinase C PKC NF kB and the activation of growth factors TGF B and vascular endothelial growth factor VEGF These factors along with the hemodynamic changes that occur lead to podocyte injury oxidative stress inflammation and fibrosis As injury worsens kidney function decreases and glomerular basement membrane GBM become more permeable and less efficient at filtration This is accompanied by a steady decline in kidney function citation needed Diagnosis edit nbsp Ultrasonography showing hyperechogenicity of the renal cortex visualized in the image as brighter than the liver Diagnosis is based on the measurement of abnormal levels of urinary albumin in a diabetic 27 coupled with exclusion of other causes of albuminuria Albumin measurements are defined as follows 28 Normal albuminuria urinary albumin excretion lt 30 mg 24h Microalbuminuria urinary albumin excretion in the range of 30 299 mg 24h Macroalbuminuria urinary albumin excretion 300 mg 24h Urinary albumin excretion can also be measured by urinary albumin creatinine ratio in a spot urine sample which is as accurate but more convenient than a 24 hour urine collection 29 dd dd dd dd dd dd dd dd dd dd It is recommended that diabetics have their albumin levels checked annually beginning immediately after a diagnosis of type 2 diabetes and five years after a diagnosis of type 1 diabetes 27 30 Medical imaging of the kidneys generally by ultrasonography is recommended as part of a differential diagnosis if there is suspicion of urinary tract obstruction urinary tract infection kidney stones or polycystic kidney disease 31 Conformation kidney biopsy should only be performed if non diabetic kidney disease is suspected citation needed Urine analysis in patients with diabetic kidney disease is often bland In cases of severely increased microalbuminuria hematuria might be present 32 fat bodies might be present in patients who develop nephrotic range proteinuria Clinical staging 33 CKDStage eGFR level mL min 1 73 m2 Stage 1 90Stage 2 60 89Stage 3 30 59Stage 4 15 29Stage 5 lt 15Staging edit To clinically stage the degree of damage in this and any kidney disease the serum creatinine is determined and used to calculate the estimated glomerular filtration rate eGFR Normal eGFR is equal to or greater than 90ml min 1 73 m2 34 On biopsy the following classification has been suggested by Tervaert et al 35 Histopathologic staging Class Description and criteriaI Mild or nonspecific changes on light microscopy and conformed GBMthickening proven by electron microscopy GBM gt 395 nm female GBM gt 430 nm male IIa Mild mesangial expansion in gt 25 of the observed mesangium Area of mesangial proliferation lt area of capillary cavity IIb Severe mesangial expansion in gt 25 of the observed mesangium Area of mesangial proliferation lt area of capillary cavity III At least one convincing nodular sclerosis Kimmelstiel Wilson lesion IV Advanced diabetic glomerulosclerosis in gt 50 of glomeruli Biomarkers edit Although albuminuria is the most frequently used marker of DN it has a limited sensitivity as many patients with diabetic nephropathy experience GFR loss and glomerulosclerosis without immediate elevation in albuminuria Many novel markers are currently being studied that potentially detect diabetic nephropathy at earlier stages and identify progression risk Cystatin C is a protein that is freely filtered in the glomeruli before it is reabsorbed and catabolized in the renal tubular cells Its serum level is independent of muscle mass making more accurate at estimating GFR than creatinine serum levels citation needed Treatment editThe goals of treatment are to slow the progression of kidney damage and control related complications Management of diabetic nephropathy currently centers over four main areas Cardiovascular risk reduction glycemic control blood pressure control as well as inhibition of the RAAS system citation needed Cardiovascular risk reduction Patients with diabetes mellitus are at significantly increased risk of cardiovascular disease which is also an independent risk factor for kidney failure Therefore it is important to aggressively manage cardiovascular risk factors in patients with diabetes mellitus and in particular those with diabetic nephropathy The main components of managing cardiovascular disease is with tobacco cessation lipid lowering therapies e g statins as well as regular exercise and healthy eating 36 In patients with kidney disease atorvastatin is preferred over other statins as it does not require dose adjustment based on GFR 37 Glycemic control Multiple studies have found a positive effect of improved glycemic control on clinical outcomes of patients with diabetic nephropathy 38 Intensive glycemic control also reduces the rate of other DM complications such as retinopathy and neuropathy Glycemic control is maintained mainly with insulin in patients with Type 1 DM and with hypoglycemic agents and or insulin in patients with type 2 DM Studies showed a decrease in microvascular complications of diabetic nephropathy with a target goal HbA1c concentration of 7 Further reduction in the HbA1c did not correlate with better outcomes and is thus not recommended in most patients as it could increase the risk of hypoglycemic episodes 39 40 Blood pressure control Multiple randomized clinical trials have demonstrated a benefit of decreasing systolic blood pressure to lt 140 mmHg in patients with diabetic nephropathy High blood pressure is associated with accelerated development of microalbuminuria over proteinuria and declining kidney function Angiotensin converting enzyme inhibitors as well as angiotensin II receptor blockers are particularly helpful in patients with diabetes to lower blood pressure and slow the progression of nephropathy 41 More intensive blood pressure lower 125 130 lt 80 in patients with diabetic mellitus has been shown to decrease the risk of progression of diabetic nephropathy as well as other diabetic complications 42 Some patients might require dual therapy to adequately control pressure in which case calcium channel blockers or diuretics are a good second line option 43 RAAS inhibition Inhibition can be achieved with multiple therapies mainly ACE inhibitors angiotensin receptor blockers direct renin inhibitors and mineralocorticoid antagonists RAAS inhibition has been proven to be the most effective therapy to slow the progression of diabetic nephropathy in all stages 44 Although RAAS blockade using more than one agent may further reduce proteinuria the risk of adverse events such as hyperkalemia acute kidney injury outweigh the potential benefits 45 Therefore it is recommended that only one agent is used in patients with DM who have hypertension or any signs of microalbuminuria or diabetic nephropathy 46 About half of insulin is metabolized and cleared by the kidneys This means that as kidney function worsens in the setting of DN some patients with insulin dependent DM may find that their regular insulin doses are lasting longer than normal or that they are experiencing an increasing frequency of hypoglycemic episodes It is also crucial to closely monitor kidney function to properly dose medications that are cleared by the kidneys Some of the most commonly used nephrotoxic medications are non steroidal anti inflammatory drugs NSAIDs such as ibuprofen 47 With worsening kidney function it might also be necessary to follow a renal diet to avoid complications such as hyperkalemia and metabolic acidosis Some evidence suggests that limiting dietary protein could slow the progression of DN but further evidence is needed to confirm this benefit 48 Patients with diabetic nephropathy might go on to develop end stage renal disease and require kidney transplantation or hemodialysis citation needed Emerging therapies edit A relatively new medication that has been approved for treatment for DM is sodium glucose cotransporter 2 SGLT2 inhibitors The mechanism of action of this drug is to the sodium glucose uptake cotransporter in the proximal tubule thereby generating naturesis and glucosuria In multiple clinical trials SGLT2 inhibitors showed improved cardiovascular outcomes in patients with DM as well a positive effect on kidney outcomes mainly a reduction in albuminuria and progression of renal damage 49 50 Other classes of diabetic medications that have been shown to have a positive effect on the progression of diabetic nephropathy are GLP 1 agonists and DPP 4 inhibitors citation needed Education and self management edit The success of diabetic nephropathy management depends greatly upon the ability of individuals to self manage this condition encompassing glycaemic control and the adoption of healthy lifestyles Appropriate self management often requires patient education and behavioural counselling However there is still insufficient evidence to draw conclusions regarding the effects regarding both benefits and harms of educational programmes for people with diabetic nephropathy 51 Further high quality studies are warranted Prognosis editDiabetic nephropathy in type 2 diabetes can be more difficult to predict because the onset of diabetes is not usually well established Without intervention 20 40 percent of patients with type 2 diabetes microalbuminuria will evolve to macroalbuminuria 52 Diabetic nephropathy is the most common cause of end stage kidney disease 13 14 which may require hemodialysis or even kidney transplantation 15 It is associated with an increased risk of death in general particularly from cardiovascular disease 13 16 Epidemiology editDiabetic nephropathy affects approximately a third of patients with type 1 and type 2 diabetes mellitus Diabetic nephropathy is responsible for about a third of cases of ESRD worldwide and an even larger fraction in the developed countries 53 Worldwide the prevalence of diabetes is projected to increase from 382 million in 2013 to over 592 million by 2035 This increase is projected to be sharpest in developed countries The prevalence of type 2 DM is particularly increasing due to the rising prevalence of obesity worldwide 54 Diabetic kidney disease progression could lead to ESRD as well as an increased risk of cardiovascular complications all of which cause a substantial economic burden The estimated cost of management of patients with ESRD due to diabetic nephropathy in the US is US 39 35 billion in 2010 55 Within developed countries certain ethnic groups such as African Americans and Native Americans are at higher risk of developing diabetic nephropathy and ESRD 56 See also editDiabetic diet Hyperbaric medicine NephrologyReferences edit a b c d e Alamo A Campagna D Di Pino A Russo C Calogero A E Polosa R Purrello F October 2019 Smoking and 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Diabetes New England Journal of Medicine 375 4 323 334 doi 10 1056 nejmoa1515920 ISSN 0028 4793 PMID 27299675 Li Ting Wu Hong Mei Wang Feng Huang Chang Quan Yang Ming Dong Bi Rong Liu Guan J 2011 06 15 Cochrane Kidney and Transplant Group ed Education programmes for people with diabetic kidney disease Cochrane Database of Systematic Reviews 6 CD007374 doi 10 1002 14651858 CD007374 pub2 PMID 21678365 Shlipak M 2011 03 15 Clinical Evidence Handbook Diabetic Nephropathy Preventing Progression American Family Physician American Family Physician 83 6 732 Retrieved 2015 06 27 Zimmet Paul Alberti K G M M Shaw Jonathan December 2001 Global and societal implications of the diabetes epidemic Nature 414 6865 782 787 Bibcode 2001Natur 414 782Z doi 10 1038 414782a ISSN 0028 0836 PMID 11742409 S2CID 4384190 Cameron Adrian J Zimmet Paul Z Atkins Robert C Shaw Jonathan E 2007 The Australian Diabetes Obesity and Lifestyle Study Profiling Diabetes and Cardiovascular Disease Risk in the Nation European Endocrinology 2 20 doi 10 17925 ee 2007 00 02 20 ISSN 1758 3772 Trivedi Hariprasad S Pang Michael M H Campbell Anne Saab Paulette April 2002 Slowing the progression of chronic renal failure Economic benefits and patients perspectives American Journal of Kidney Diseases 39 4 721 13 doi 10 1053 ajkd 2002 31990 ISSN 0272 6386 PMID 11920337 Disease Ethnicity amp 2018 10 17 Correction Ethn Dis 2010 20 Suppl 1 S1 60 S1 64 Ethnicity amp Disease 28 4 586 doi 10 18865 ed 28 4 586 ISSN 1945 0826 PMC 6200305 PMID 30405305 Further reading edit Effects of renin angiotensin system blockers on renal outcomes and all cause mortality in patients with diabetic nephropathy an updated meta analysis www crd york ac uk Retrieved 2015 07 02 Gross JL de Azevedo MJ Silveiro SP Canani LH Caramori ML Zelmanovitz T January 2005 Diabetic nephropathy diagnosis prevention and treatment Diabetes Care 28 1 164 76 doi 10 2337 diacare 28 1 164 PMID 15616252 Tziomalos K Athyros VG 2015 Diabetic Nephropathy New Risk Factors and Improvements in Diagnosis The Review of Diabetic Studies 12 1 2 110 8 doi 10 1900 RDS 2015 12 110 PMC 5397986 PMID 26676664 Kume S Koya D Uzu T Maegawa H 2014 Role of nutrient sensing signals in the pathogenesis of diabetic nephropathy BioMed Research International 2014 315494 doi 10 1155 2014 315494 PMC 4122096 PMID 25126552 Doshi SM Friedman AN August 2017 Diagnosis and Management of Type 2 Diabetic Kidney Disease Clinical Journal of the American Society of Nephrology 12 8 1366 1373 doi 10 2215 CJN 11111016 PMC 5544517 PMID 28280116 External links edit nbsp Scholia has a topic profile for Diabetic nephropathy Retrieved from https en wikipedia org w index php title Diabetic nephropathy amp oldid 1215798036, wikipedia, wiki, book, books, library,

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