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Peritoneal dialysis

Peritoneal dialysis is a form of renal replacement therapy used to treat kidney failure by utilizing the peritoneum, the thin membrane lining the abdominal cavity, as a natural semipermeable filter to remove waste products, excess fluid, and electrolytes from the blood. A soft catheter is surgically implanted into the abdomen to allow the infusion and drainage of a sterile dialysis solution, known as dialysate, which is introduced into the peritoneal cavity, dwells for several hours to facilitate diffusion across the peritoneal membrane, and is then drained, carrying away accumulated toxins. This process mimics the kidneys' filtration function and can be performed at home, offering a needle-free alternative to hemodialysis for patients with end-stage renal disease. The procedure typically involves multiple exchanges per day, with the dialysate absorbing urea, creatinine, and other uremic toxins through osmosis and diffusion driven by concentration gradients. Two primary types exist: continuous ambulatory peritoneal dialysis (CAPD), which relies on manual exchanges performed 3 to 5 times daily without machinery, allowing the solution to dwell for 4 to 6 hours between cycles; and automated peritoneal dialysis (APD), also called continuous cycling peritoneal dialysis (CCPD), which uses a programmable machine (cycler) to automate exchanges, often overnight during sleep, typically completing 3 to 5 cycles. Both methods require patient training, usually lasting 1 to 2 weeks, and regular monitoring of dialysis adequacy through blood tests and peritoneal equilibration tests to ensure effective clearance. Peritoneal dialysis provides several advantages over in-center , including greater lifestyle flexibility, as treatments can be integrated into daily routines at home, work, or while traveling, and potentially better preservation of residual function with more frequent, gentler filtration. It also avoids vascular access complications and may allow for a less restrictive due to continuous waste removal, though patients must manage fluid intake and adhere to a low-sodium, potassium-controlled regimen. However, it carries notable risks, such as —an infection of the caused by bacterial contamination of the site or dialysate, which can lead to , fever, and cloudy effluent, requiring prompt antibiotic treatment—and other complications like hernias from increased intra-abdominal pressure or weight gain from dextrose absorption in the dialysate. Suitability depends on factors like , with contraindications including extensive prior surgeries, , or , and long-term use may result in peritoneal membrane sclerosis, potentially necessitating a switch to .

Medical Uses

Indications

Peritoneal dialysis (PD) serves as a primary for patients with end-stage renal disease (ESRD), where it facilitates the removal of waste products such as and , excess fluid through , and maintenance of balance when native function is insufficient. This modality is particularly indicated for individuals with stage 5 who require long-term dialysis support, offering a home-based alternative that aligns with quality-driven care models emphasizing patient-centered outcomes. PD is suitable for managing (AKI) in select cases, especially where hemodynamic instability or limited vascular access precludes , as it provides effective solute clearance, acid-base correction, and fluid management without systemic anticoagulation. It is also recommended for pediatric patients, particularly infants and children aged 0-5 years, due to challenges with vascular access in small vessels and the need for gentle, continuous that supports ; in this population, PD is often the preferred initial modality for ESRD. Additionally, PD is indicated for adults with vascular access failure, , or intolerance to , such as those with congestive or prosthetic valvular disease, where it avoids the risks associated with central venous catheters. One key benefit of PD is its superior preservation of residual renal function compared to , with studies showing a more gradual decline in glomerular filtration rate over time, which contributes to improved survival, nutritional status, and . Guidelines from organizations like Kidney Disease: Improving Global Outcomes (KDIGO) endorse PD as a first-line option for suitable patients, emphasizing shared based on preferences, , and local resources, particularly in regions adopting a "PD first" approach for its cost-effectiveness and autonomy benefits.

Contraindications

Peritoneal dialysis (PD) has few absolute contraindications, but careful patient selection is essential to prevent adverse outcomes such as ineffective dialysis or severe complications. Absolute contraindications typically involve conditions that compromise the integrity or function of the peritoneal membrane or cavity, rendering PD unsafe or ineffective. Absolute contraindications include documented ultrafiltration failure due to loss of peritoneal membrane function, often from prior severe peritonitis or sclerosing peritonitis. Extensive abdominal adhesions that cannot be lysed laparoscopically, leading to loss of peritoneal volume, also preclude PD by limiting dialysate flow and distribution. Unrepairable abdominal wall hernias with loss of domain, active intra-abdominal infections (such as unresolved peritonitis or inflammatory bowel disease), and uncorrectable intra-abdominal pathologies like enteric fistulas or recent bowel perforation are similarly prohibitive. Severe protein-calorie malnutrition with proteinuria exceeding 10 g/day further contraindicates PD due to risks of worsening nutritional status and poor solute clearance. Relative contraindications encompass factors that increase complication risks but may be mitigated with careful management or alternative approaches. These include (BMI >40), which complicates placement and increases hernia or leak risks; , associated with higher rates of dialysate leaks and hernias; and severe , where fluid overload management may be challenging despite potential benefits. Repairable hernias, recent (within 4-6 weeks), presence of ostomies or stomas, and social barriers such as unsuitable home environments or inability to maintain sterility also fall into this category, often requiring evaluation for feasibility. Patient evaluation for PD suitability involves a comprehensive preoperative assessment, including detailed , , and to visualize the . Computed tomography () scans or plain radiographs are commonly used to detect adhesions, hernias, or other structural abnormalities that could impair dialysate flow. risk stratification and on capabilities are integral, with multidisciplinary input from nephrologists and surgeons to weigh risks. In patients with , PD carries elevated risks of infectious complications, such as , due to impaired immune responses and vascular changes, necessitating stringent glycemic control and hygiene protocols. Recent heightens the likelihood of adhesions or poor membrane integrity, potentially leading to technique failure, and thus requires delayed initiation or imaging confirmation of resolution. For cases where PD is contraindicated, serves as the primary alternative .

Mechanism of Action

Peritoneal Physiology

The peritoneum is a serous membrane that lines the abdominal cavity and covers the visceral organs, serving as a semi-permeable barrier in peritoneal dialysis. It consists of a single layer of mesothelial cells forming the outermost surface, supported by a submesothelial interstitium of connective tissue that houses an extensive network of blood capillaries and lymphatic vessels. This architecture enables efficient solute and fluid transport: blood capillaries provide the primary site for diffusion and ultrafiltration, while lymphatic vessels facilitate the drainage of excess fluid and proteins from the peritoneal cavity back into the systemic circulation. The core physiological principles underlying peritoneal dialysis are for solute removal and for fluid extraction. Small molecular weight solutes, such as and (with molecular weights below 600 ), move from the higher concentration in blood within peritoneal capillaries to the lower concentration in the instilled dialysate via passive across the . Concurrently, the hypertonic dialysate, typically containing glucose as an , generates a crystalloid gradient that draws water from the bloodstream into the through , primarily via small pores and aquaporin-1 water channels in capillary endothelia. This process is governed by forces, where the osmotic gradient outweighs hydrostatic pressure differences to achieve net fluid removal. Net during a dwell is determined by the balance of transcapillary fluid influx driven by and fluid efflux, approximated as the product of the mass transfer area coefficient (MTAC)—which reflects the effective peritoneal surface area and permeability for water transport—multiplied by , minus lymphatic . The MTAC, with units of per time, quantifies the maximal diffusive potential across the , influenced by vascular and characteristics; lymphatic , typically 1-2 mL/min in adults, continuously reabsorbs dialysate and limits net gains, especially in prolonged dwells. In equation form: \text{Ultrafiltration volume} = (\text{MTAC} \times \text{time}) - \text{lymphatic absorption} This model highlights how sustained osmotic gradients are essential to counterbalance reabsorption for effective therapy. Efficiency of peritoneal transport varies individually, classified by peritoneal equilibration test (PET) results into high, high-average, low-average, or low transporter types based on the dialysate-to-plasma (D/P) ratio of creatinine after a 4-hour dwell with 2.27% glucose dialysate. High transporters exhibit rapid solute equilibration (D/P creatinine >0.81) due to increased membrane permeability and vascular surface area, enabling quick clearance but risking early dissipation of the osmotic gradient and reduced ultrafiltration. Low transporters (D/P <0.50) show slower diffusion, preserving longer osmotic efficacy for better fluid removal but potentially inadequate solute clearance; average types (D/P 0.50-0.81) balance both processes optimally for most patients. The PET, standardized since the 1980s, guides personalized dialysis prescriptions by assessing these inherent physiological differences.

Dialysis Modalities

Peritoneal () encompasses several modalities tailored to individual patient needs, primarily continuous ambulatory (CAPD) and automated (APD), which differ in their delivery methods and scheduling to optimize solute clearance and while accommodating factors. These approaches leverage the peritoneum's diffusive and convective properties for waste removal, with variations in exchange frequency and dwell duration to match peritoneal characteristics. CAPD involves manual exchanges performed by , typically 3 to 5 times daily, using to fill and drain 2 to 2.5 liters of dialysate into the . Each exchange consists of an inflow phase, a dwell period of approximately 4 to 6 hours during which solutes and excess fluid are removed, and a phase, allowing patients to maintain without reliance on . This modality is particularly suitable for patients with flexible schedules, good manual dexterity, and lower solute transport rates, as longer dwells support adequate clearance in those with preserved residual renal function. In contrast, APD employs a cycler machine to automate exchanges, usually conducted overnight for 8 to 10 hours, enabling shorter dwell times of 1 to 3 hours per cycle and reducing daytime interruptions. Common subtypes include continuous cycling PD (CCPD), which features multiple cycles with a long daytime dwell, and nightly intermittent PD (NIPD), which omits daytime dwells for patients with sufficient residual kidney function to handle diurnal clearance. APD is often preferred for high or high-average membrane transporters to prevent rapid glucose absorption and fluid reabsorption during extended dwells, and it may incorporate icodextrin solutions for the daytime period to enhance ultrafiltration. Hybrid modalities blend elements of CAPD and , such as tidal PD, where partial drainage occurs before refilling to minimize discomfort or improve efficiency in patients with incomplete drainage, or combined nocturnal with manual daytime exchanges. These options provide customization for specific clinical scenarios, like varying transport status or lifestyle demands. Selection of a modality is guided by patient lifestyle, residual renal function, and peritoneal membrane characteristics assessed via the peritoneal equilibration test (). For instance, CAPD suits mobile individuals prioritizing daytime freedom and travel ease, while benefits those with demanding schedules, employment needs, or high transport rates requiring shorter dwells to maintain volume control. Guidelines recommend offering both modalities and tailoring prescriptions to preserve residual function and , with no superior outcomes demonstrated between CAPD and in randomized studies.

Procedure

Catheter Insertion

Peritoneal dialysis requires the placement of a flexible into the to facilitate the infusion and drainage of dialysate, typically performed as a minor surgical procedure prior to initiating . The serves as the permanent access point, designed for long-term use and comfort. Insertion is generally carried out under sterile conditions in an operating room or procedural suite, with the choice of technique influenced by anatomy, expertise, and institutional resources. Common catheter types include the Tenckhoff design, which features a straight or curled (coiled) intraperitoneal segment made of for flexibility and reduced tissue irritation, often equipped with one or two Dacron cuffs to promote tissue ingrowth for secure fixation and to act as a barrier against . The double-cuffed variant is preferred for chronic use, with the proximal cuff positioned in the preperitoneal space and the distal cuff subcutaneously to anchor the device. Swan-neck catheters, a modification of the Tenckhoff, incorporate a pre-formed arc or swan-neck curve between the cuffs to optimize exit-site direction and minimize tension on the tunnel, potentially lowering complication rates. Insertion techniques vary to accommodate different clinical scenarios. The open surgical method involves a midline abdominal incision to create a purse-string suture around the for catheter entry, followed by subcutaneous tunneling to the exit site, typically performed under with . Percutaneous insertion uses the , where a needle punctures the under or fluoroscopic guidance, followed by guidewire dilation and catheter advancement, suitable for urgent cases and often done with alone. Laparoscopic placement, under general , employs small trocars for direct visualization, enabling adjunct procedures like omentopexy (fixation of omentum) or adhesiolysis to prevent future obstruction, and is recommended for patients with prior abdominal surgeries per ISPD guidelines. Following insertion, a break-in period of 2-4 weeks is standard to allow peritoneal and cuff incorporation, during which dialysis is often delayed or limited to low-volume (e.g., 500 mL) dwells to minimize risk; however, in urgent-start peritoneal dialysis protocols, may begin within 1-14 days using low-volume dwells to minimize risks, as per recent guidelines. Temporary may bridge this interval if needed. The exit site is dressed and left undisturbed for at least 7 days to immobilize the , with daily inspections for signs of issues thereafter. Catheter position is confirmed post-procedure via plain to ensure the tip resides in the true , away from the bowel or omentum. Complications during insertion are uncommon but include bleeding from vascular injury, managed with compression or hemostatic agents in most cases, and catheter malposition, which can occur in percutaneous placements and may require immediate guidewire repositioning or laparoscopic revision. Bowel perforation is a rare but serious risk, particularly with blind percutaneous approaches, necessitating prompt surgical intervention. Adherence to ISPD-recommended protocols, such as preoperative imaging and experienced operators, helps mitigate these risks.

Dialysis Exchanges

In peritoneal , the core process of exchanges involves the of dialysate into the peritoneal , a dwell period for solute and removal, and subsequent drainage of the used . Typically, 2 to 2.5 liters of warmed dialysate are infused over 10 to 20 minutes via or an automated cycler connected to the indwelling peritoneal . The then dwells for 4 to 8 hours, depending on the modality—shorter for automated peritoneal () cycles and longer for continuous ambulatory peritoneal (CAPD) overnight exchanges—allowing osmotic gradients to facilitate the removal of waste products like and excess through the peritoneal . Drainage occurs passively by or with assistance, typically completing within 20 to 30 minutes, after which a new exchange begins; in CAPD, patients perform 3 to 5 manual exchanges daily, while automates 4 to 6 overnight cycles. Dialysate solutions are tailored to patient needs, with glucose-based formulations being the most common, available in concentrations of 1.5%, 2.5%, or 4.25% to generate varying osmotic pressures for . For long-dwell periods, such as the daytime exchange in or overnight in CAPD, icodextrin—a glucose —provides sustained without rapid absorption, improving fluid removal compared to standard glucose solutions. Amino acid-based solutions serve as alternatives, particularly for malnourished patients, offering nutritional benefits alongside while matching the of low-glucose options. Adequacy of dialysis exchanges is monitored through clearance metrics to ensure effective solute removal. The weekly /V urea target, which quantifies clearance relative to volume, is set at greater than 1.7, combining peritoneal and residual renal contributions. Similarly, normalized clearance should exceed 50 L/week per 1.73 m² to confirm sufficient small-solute clearance. In emergencies or resource-limited settings, improvised peritoneal dialysis exchanges may be necessary when standard solutions are unavailable, utilizing sterile saline or locally sourced fluids with careful sterile to perform manual inflows and outflows.

Patient Management

Patient management in peritoneal dialysis emphasizes comprehensive , vigilant , tailored modifications, and timely transitions to therapies when necessary to optimize outcomes and patient independence. Training programs for peritoneal dialysis typically last 1 to 2 weeks and are conducted in-center with a one-to-one nurse-to-patient ratio to ensure mastery of essential skills. These programs focus on aseptic techniques for safe connections during exchanges, troubleshooting common issues such as alarms on automated cyclers, and proper exit-site care to prevent complications. Sessions, often 1 to 3 hours daily and totaling at least 15 hours, incorporate hands-on practice with mannequins, videos, and step-by-step guidance to build confidence in performing procedures independently. Home is crucial for detecting early changes in status and ensuring adequacy. Patients are advised to record daily weights, , and, if diabetic, glucose levels to track and metabolic control, with remote devices sometimes facilitating data transmission to healthcare providers. Periodic laboratory tests, typically monthly or quarterly, assess adequacy through metrics like Kt/V urea and clearance, alongside nutritional markers such as and protein intake to evaluate overall well-being. Lifestyle adaptations support long-term adherence and health maintenance. A renal diet limiting potassium and phosphorus intake—such as restricting bananas, potatoes, and dairy—helps manage levels, while adequate protein consumption preserves . Exercise should be moderate, like walking, to avoid increasing intra-abdominal pressure that could lead to hernias; heavy lifting and straining are discouraged. For travel, patients plan ahead by arranging supply shipments to destinations and coordinating with local centers if needed, ensuring continuity of exchanges as the core activity. If peritoneal dialysis fails due to inadequate clearance or other issues, transition to or regimens combining both modalities may be required to maintain solute and fluid removal. approaches, such as once-weekly supplemented with daily peritoneal dialysis, can improve outcomes like cardiovascular stability without fully abandoning home-based care.

Complications

Infectious Risks

Peritonitis represents the most significant infectious complication in peritoneal dialysis (PD), posing a primary threat to the therapy's long-term viability. The incidence of PD-related has improved over time, with current International Society for Peritoneal Dialysis (ISPD) targets recommending no more than 0.40 episodes per patient-year at risk, though rates can vary between 0.2 and 0.5 episodes per patient-year in practice. Common causes include touch contamination during exchanges and progression from exit-site infections, with predominant pathogens being Gram-positive organisms such as coagulase-negative staphylococci and . Symptoms typically manifest as , cloudy peritoneal effluent, and sometimes fever or , necessitating prompt recognition to prevent severe outcomes like technique failure or mortality, which occurs in approximately 5% of episodes. Prevention strategies emphasize rigorous aseptic protocols, including thorough patient training on sterile exchange techniques and daily exit-site care to minimize risks. Antibiotic prophylaxis at the time of insertion, using agents like or cephalosporins, significantly reduces early postoperative infections. Additionally, biocompatible solutions, which are pH-neutral and - or bicarbonate-buffered, help attenuate peritoneal and enhance defenses, potentially lowering rates by improving compared to conventional glucose-based solutions. Treatment of peritonitis involves immediate empirical intraperitoneal (IP) antibiotics, typically for Gram-positive coverage combined with ceftazidime or an for Gram-negative organisms, administered continuously or intermittently to achieve high peritoneal concentrations. Therapy is then tailored based on effluent culture and results, with most episodes resolving within 48-72 hours if appropriately managed. cases, defined as failure to respond after 5 days of therapy, often require catheter removal to prevent recurrent or peritoneal sclerosis. Exit-site and tunnel infections, while less frequent than peritonitis, contribute to its development and occur at rates of approximately 0.4 episodes per patient-year, with ISPD targets aiming for no more than 0.40 episodes per year at risk. These infections present with erythema, purulent discharge, or tenderness along the catheter tract and are primarily caused by S. aureus or Pseudomonas aeruginosa. Management includes empirical oral antibiotics such as cephalosporins targeting S. aureus, alongside topical agents like mupirocin or gentamicin applied to the exit site; persistent or tunnel-involving cases may necessitate prolonged therapy (up to 3 weeks) or catheter revision.

Fluid and Metabolic Issues

Ultrafiltration failure in peritoneal dialysis represents a significant challenge, characterized by inadequate removal of excess from the body, often resulting in fluid overload and increased cardiovascular morbidity. This condition arises primarily from two mechanisms: high peritoneal transporter status, where rapid solute leads to quick dissipation of the osmotic due to enhanced vascular surface area and glucose , and sclerosis, involving that impairs free water across the . In patients without residual renal function, ultrafiltration failure affects up to 21% of those on long-term therapy, exacerbating and contributing to and . typically involves the use of hypertonic glucose solutions, such as 3.86% concentrations, to restore the osmotic and achieve net volumes of approximately 635 mL over a 4-hour dwell. The volume control in peritoneal dialysis is governed by the net ultrafiltration equation, which balances fluid influx and efflux: \text{Net ultrafiltration} = (\text{osmotic gradient} \times \text{hydraulic permeability}) - \text{lymphatic reabsorption} Here, the osmotic gradient, primarily driven by glucose in the dialysate, promotes transcapillary through hydraulic permeability (LpA, the product of and effective peritoneal surface area), while lymphatic reabsorption, averaging 1.5 mL/min, counteracts net fluid removal. Disruptions in this equilibrium, such as reduced hydraulic permeability from vascular changes or accelerated lymphatic , further contribute to fluid imbalances. Glucose-based dialysate solutions lead to substantial systemic absorption, with patients typically taking in 100-200 g/day (equivalent to 320-640 kcal/day), promoting and that elevate cardiovascular risk. This absorption results in elevated fasting blood glucose levels and unfavorable lipid profiles compared to . Peritoneal dialysis also induces notable protein losses into the dialysate, ranging from 5-15 g/day, predominantly albumin-based (6-8 g/day on average), which depletes nutritional reserves and heightens the risk of and protein-energy wasting. These losses correlate with lower and are compounded by inadequate dietary intake in dialysis patients. Concurrently, shifts occur, with (serum <3.5 mEq/L) affecting 10-36% of patients due to potassium-free dialysate (losses of 25-30 mEq/day), poor nutritional potassium intake, and intracellular shifts, often linked to and volume status.

Long-Term Effects

Prolonged peritoneal dialysis can lead to progressive changes in the peritoneal membrane, resulting in dysfunction characterized by a loss of capacity. This acquired condition arises from repeated exposure to dialysis solutions, causing structural alterations such as increased vascular density and , which impair the membrane's ability to remove fluid effectively. The peritoneal equilibration test (), using a 4-hour dwell with 2.25% or 3.86% glucose and measuring the dialysate-to-plasma ratio, is the standard method to assess solute and identify high or low transporters, with failure indicated by net volumes below 400 mL during a 4.25% dextrose dwell. Management often involves switching to icodextrin or hypertonic solutions initially, but severe cases may necessitate transitioning to to prevent further deterioration. Encapsulating peritoneal sclerosis (EPS) represents a rare but severe fibrotic response of the peritoneum, typically emerging after more than five years of dialysis, with incidence rates ranging from 0.7% to 2.8% overall and rising to 17% after 15 years. Recent data suggest the incidence of EPS has been decreasing with the use of biocompatible solutions and better patient management. This condition involves the formation of a fibrous cocoon around the intestines, leading to symptoms such as abdominal pain, nausea, vomiting, weight loss, bowel obstruction, and ascites, often accompanied by ultrafiltration failure. Diagnosis relies on clinical presentation and computed tomography imaging showing peritoneal thickening and encapsulation, while treatment includes immediate discontinuation of peritoneal dialysis, nutritional support, corticosteroids like prednisolone, and, in advanced cases, surgical interventions such as enterolysis or peritonectomy to remove the fibrous layer. Despite these measures, EPS carries a high mortality rate of 35% to 69%, underscoring its life-threatening nature in long-term patients. Chronic and associated with long-term peritoneal accelerate cardiovascular and diseases, contributing to elevated mortality risks, particularly beyond three to five years of therapy. remains the leading cause of death, accounting for over 40% of fatalities, driven by (e.g., elevated levels) and malnutrition markers like low , which promote and vascular . Similarly, chronic kidney disease-mineral disorder (CKD-MBD) worsens, with increased risks of fractures and further cardiovascular complications due to disordered calcium-phosphate metabolism and ongoing . These factors form a vicious cycle, where exacerbates , leading to higher all-cause mortality rates compared to shorter-term . Increased intra-abdominal pressure from dialysate volumes in peritoneal dialysis predisposes patients to mechanical complications like hernias and over time. Hernias, particularly inguinal and umbilical types, occur due to weakened abdominal walls under sustained pressure, with higher incidence in peritoneal dialysis compared to , often requiring surgical repair to continue therapy. arises from distension and altered posture during dwells, compounded by high fill volumes that elevate pressure and strain paraspinal muscles, though it can be mitigated by optimizing techniques or using lower volumes. These issues highlight the need for regular monitoring of intra-abdominal pressure to prevent progression.

Comparison to Hemodialysis

Clinical Advantages

Peritoneal dialysis (PD) offers several clinical advantages over , particularly in enhancing patient autonomy and physiological stability during the initial years of . Unlike , which requires vascular access and frequent clinic visits, PD utilizes the peritoneal membrane for continuous solute and fluid removal, enabling home-based treatment that aligns better with daily life. This modality has been associated with improved early rates, with studies indicating a survival benefit for PD patients in the first 1-2 years post-initiation compared to those on . However, long-term is often comparable or may favor depending on patient factors such as age and comorbidities. A primary clinical advantage of PD is its flexibility, allowing patients to perform dialysis at home, work, or while traveling without the need for needles or vascular access sites. This home-based approach empowers greater independence, reduces disruptions to employment or family responsibilities, and is especially beneficial for individuals in remote areas or those with demanding schedules. For instance, continuous ambulatory PD involves manual exchanges that integrate into routine activities, while automated PD occurs overnight, freeing daytime hours. PD also excels in preserving residual kidney function (RKF), with a slower rate of decline attributed to reduced hemodynamic stress and the use of biocompatible fluids. This preservation contributes to better fluid and solute management in the early treatment phase, correlating with improved survival outcomes during the first two years. The steady-state clearance provided by frequent, smaller-volume exchanges in PD supports this gentler preservation compared to the intermittent nature of . Hemodynamically, PD provides superior stability by avoiding rapid shifts in blood volume and pressure associated with sessions, resulting in fewer fluctuations and lower post-treatment blood pressure levels. This is particularly advantageous for patients with or the elderly, as it imposes less strain on the cardiovascular system, maintaining higher cardiac ejection fractions and reducing risks of intradialytic . In terms of , PD patients report higher satisfaction and health-related metrics, such as elevated Kidney Disease Quality of Life (KDQOL) scores in domains like burden of (38.0 vs. 31.5 at 3 months) and physical component summaries. Prospective studies confirm that a notable proportion of patients initiating PD express for it due to these perceived benefits, with up to 85% rating overall care as excellent compared to 56% in groups.

Limitations and Risks

Peritoneal dialysis () is associated with a notable risk of technique failure, defined as the need to switch to due to inability to continue PD effectively. Studies indicate that approximately 30-40% of patients experience technique failure within 2-3 years, primarily driven by recurrent infections such as and patient from the demands of self-management. In one large cohort of incident US PD patients, technique survival was 61.2% at 2 years and 45.2% at 3 years, with as the leading cause. , often linked to psychosocial factors like and difficulty adhering to daily routines, contributes significantly to dropout. Compared to , PD provides lower clearance for larger solutes due to the peritoneal membrane's limited diffusive capacity for high-molecular-weight molecules. This inefficiency becomes particularly pronounced in anuric patients, where residual renal function is absent, often necessitating intensified regimens such as larger dwell volumes, additional exchanges, or adjunct therapies like icodextrin to augment and solute removal. For instance, clearance of middle- and large-molecular-weight uremic toxins is reduced as solute size increases, potentially leading to inadequate adequacy (Kt/V) targets without supplementation, and in severe cases, hybrid approaches combining PD with hemodiafiltration may be required to achieve sufficient clearance. The infectious burden in PD is substantial, with peritonitis representing a higher and more frequent risk than vascular access infections in . PD patients face a 2- to 3-fold increased likelihood of severe infections compared to home hemodialysis users, with first-year incidence rates of 35% for continuous ambulatory PD and 25% for automated PD versus 11% for home HD. Peritonitis episodes occur at a rate of approximately 0.2-0.4 per patient-year, often leading to technique failure, hospitalization, and damage, whereas infections are typically confined to access sites like fistulas or grafts. PD imposes a significant burden due to its requirement for daily self-administration and substantial home storage needs, making it less suitable for individuals reliant on caregivers or those with cognitive impairments. must perform 4-5 exchanges daily for continuous PD or manage overnight automated cycles, alongside storing large volumes of dialysate bags (often requiring dedicated space equivalent to a small room), which can overwhelm living arrangements and contribute to non-adherence. This daily commitment exacerbates , particularly for cognitively impaired —prevalent in approximately 30-50% of PD users—who may struggle with technique mastery, increasing dropout risk without robust support.

History

Early Innovations

The origins of peritoneal dialysis trace back to the early 20th century, when researchers explored the peritoneum's potential as a for solute removal in . In the 1920s, Georg Ganter conducted the first animal experiments, ligating ureters in rabbits and guinea pigs to induce and then infusing isotonic saline into the to mimic . Ganter extended these efforts to humans in 1923, attempting the procedure on a with postpartum renal using a hollow needle and sterile saline, though it proved unsuccessful due to inadequate solute clearance and the patient's death from infection. These initial trials highlighted the peritoneum's dialytic capacity but underscored the need for improved techniques to manage infection risks. Human applications advanced in the 1930s, primarily for treating acute . In , J.B. Wear, I.R. Sisk, and A.J. Trinkle at Wisconsin General Hospital successfully employed continuous peritoneal lavage in a patient with urinary obstruction-induced acute renal failure, sustaining the treatment until the obstruction resolved and renal function recovered. This marked one of the earliest documented successes, demonstrating PD's viability for short-term support in acute cases, though limitations such as fluid imbalance and persisted. Refinements in the and shifted toward intermittent lavage to enhance safety and efficacy. In 1946, Howard A. Frank, Arnold M. Seligman, and Jacob Fine introduced a closed-loop system with dual catheters and a hanging bottle apparatus, successfully treating approximately 150 patients with acute renal failure, including survival in cases of lasting up to four days, while reducing risks. S.S. Rosenak contributed to access improvements, developing an enhanced drain for peritoneal lavage in 1948 to facilitate better fluid exchange, though he later abandoned due to recurrent . By 1952, Arthur Grollman popularized intermittent lavage using a single flexible , and in 1959, Morton H. Maxwell standardized the technique with 2-liter hypertonic glucose exchanges, making it a widely adopted method for acute management. The 1960s brought pivotal innovations in access for more reliable use. In 1962, R.A. Palmer, collaborating with Wayne Quinton, developed the first indwelling silicone catheter for chronic peritoneal access, enabling repeated dialyses without repeated punctures. Henry Tenckhoff refined this in 1968 by introducing the straight Tenckhoff catheter with Dacron cuffs and a trocar insertion method, which minimized migration and infection while supporting intermittent PD for end-stage renal disease. Despite these advances, early PD faced significant challenges, including frequent peritonitis from repeated access and inadequate sterility, restricting it to short-term, hospital-based applications until the 1970s introduction of continuous ambulatory PD (CAPD) enabled longer-term home use. These foundational developments laid the groundwork for the transition to modern automated peritoneal dialysis systems.

Contemporary Developments

In the 1970s and 1980s, continuous ambulatory peritoneal dialysis (CAPD) gained widespread adoption following its introduction by Dimitrios G. Oreopoulos and colleagues, who developed a simple, safe allowing to perform exchanges manually throughout the day without specialized , thereby improving and independence. Concurrently, automated peritoneal dialysis () emerged in the 1980s with the development of cycler machines, which automated exchanges during nighttime to enhance treatment compliance, reduce manual burden, and minimize daytime disruptions for . During the 1990s and 2000s, advancements in dialysate formulations addressed biocompatibility concerns, particularly the damage caused by conventional glucose-based solutions with high glucose degradation products (GDPs). Neutral , low-GDP solutions were introduced to mitigate peritoneal and long-term structural changes, demonstrating improved preservation of residual renal function and reduced in clinical studies. Additionally, icodextrin, a glucose osmotic , became available for long dwells, providing sustained through rather than crystalloid , which proved effective in managing fluid overload in high-transporter patients and extending technique survival. From the 2010s onward, technologies have integrated into peritoneal dialysis practice, with mobile applications and connected cyclers enabling real-time data transmission of volumes, therapy adherence, and to healthcare providers, thereby facilitating early intervention and reducing hospitalization rates. lock solutions, such as gentamicin or taurolidine instilled into catheters post-exchange, have been employed to prevent formation and recurrent , showing efficacy in eradicating persistent infections when combined with . The International Society for Peritoneal Dialysis (ISPD) updated its peritonitis prevention guidelines in 2022, recommending targets of no more than 0.40 episodes per patient-year at risk and emphasizing strategies like routine exit-site care, avoidance of , and limited use of histamine-2 receptor antagonists to lower enteric peritonitis risk. Post-2023 developments include trials of wearable peritoneal dialysis devices, such as the AWAK PD system, which received FDA Breakthrough Device Designation in 2019 and has demonstrated feasibility in pre-pivotal and ongoing late feasibility studies as of 2025, allowing ambulatory treatment by automating fluid regeneration and exchanges in a portable format for improving patient mobility and . Emerging research on AI-optimized cycles explores algorithms to personalize APD prescriptions based on patient-specific transport characteristics and residual kidney function, with potential to reduce adverse events through predictive adjustments to dwell times and volumes.

Epidemiology

Global Trends

Peritoneal dialysis () accounts for approximately 11% of the global population, with more than 272,000 patients receiving this as of 2016, a figure that has remained relatively stable in recent years. By 2024, this proportion continues to hover around 11% worldwide, reflecting limited overall expansion despite regional variations in adoption. The International Society of Nephrology's 2023 Global Kidney Health Atlas reports availability in 79% of surveyed countries, with a of 37.9 patients per million population, though this represents only a small fraction of total kidney replacement . Key factors influencing PD utilization include its cost-effectiveness, particularly in low- and middle-income countries (LMICs), where home-based delivery minimizes and staffing needs compared to (HD). Policy incentives, such as bundled payment models in high-income settings like the , have further promoted PD by aligning financial reimbursements with home therapies. In LMICs, PD center density increased by 29.4% from 2019 to 2023, supporting gradual growth despite challenges like fluid costs and training gaps. Trends show varying PD use in and , with high adoption in countries like and historically in , though recent policy changes in have reduced utilization to about 15.5% by 2023. In contrast, utilization is increasing in the United States but stable or declining in due to preferences for in-center HD and concerns over long-term technique survival. Regarding outcomes, PD mortality rates are comparable to HD in the first year but higher over the long term, particularly among older patients with comorbidities.

Regional Disparities

Regional disparities in the utilization of peritoneal () are pronounced, with adoption rates varying significantly across continents due to differences in healthcare infrastructure, policy incentives, and resource availability. Globally, accounts for approximately 11% of all patients, but this proportion fluctuates widely by region. In East and , utilization remains among the highest worldwide, driven historically by government subsidies and "PD-first" policies that promoted home-based therapy as a cost-effective alternative to (). For instance, in , 68% of prevalent patients were on as of 2022, supported by comprehensive public funding and training programs. , which implemented a PD-first policy in 2008, saw peak utilization rates exceeding 60% of incident patients in the early due to universal coverage subsidies; however, following a policy shift in 2022 allowing greater patient choice, the proportion declined to about 15.5% of prevalent patients by 2023 (23,714 on out of 152,714 total). These trends reflect ongoing efforts in the region to balance accessibility with evolving patient preferences post-policy adjustments. In the Americas, PD use is moderate in but higher in , influenced by cost considerations and limited HD infrastructure in some areas. In the United States, 12.1% of prevalent end-stage renal disease patients were on PD in 2022, with growth attributed to reimbursement incentives and home dialysis promotion, rising from 8.8% a decade earlier. Canada reports around 20% of dialysis patients on PD, bolstered by provincial programs emphasizing home therapies. In contrast, Latin American countries like exhibit higher adoption, with PD prevalence reaching 474 patients per million population (pmp)—one of the highest globally—reflecting subsidized programs that favor PD for its lower infrastructure demands, though exact proportions have stabilized around 40-50% amid increasing HD availability. Europe and Africa show the lowest PD utilization, primarily due to well-established HD networks and logistical challenges. In , PD comprises only 5-10% of dialysis treatments overall, with higher rates in Scandinavian countries (around 20-30%) compared to Eastern and Central (under 5%), where HD infrastructure predominates despite availability in nearly all nations. In , PD prevalence is critically low at a median of 1.1 pmp, available in just 48% of countries, with sub-Saharan regions facing severe barriers such as unreliable supply chains for PD fluids and catheters, limiting use to under 5% of dialysis patients even in facilities offering it, like (23.3 pmp). Post-COVID-19 trends have slightly favored PD in high-resource settings like the and parts of , with a 37.5% increase in prevalent PD patients from 2013 to 2022, driven by preferences for home-based to minimize infection risks during pandemics.

Society and Culture

Economic Factors

Peritoneal dialysis () generally incurs lower annual costs compared to (HD) on a global scale, with median costs estimated at approximately $18,959 per patient per year for PD, versus $19,380 for HD (as of data). In high-income countries like the , however, annual Medicare expenditures for PD patients averaged around $56,000 per patient in recent years, adjusted for inflation to 2024 figures, reflecting bundled payments that cover supplies and services but are influenced by higher supply demands such as dialysis solutions and s. Globally, costs vary significantly by income level; for example, PD averaged $7,005 per patient annually in lower-middle-income countries, $30,064 in low-income countries, and $27,206 in high-income settings (as of ), often due to subsidized supplies and reduced needs. Upfront per-patient costs for PD are typically involving placement at around $5,000–10,000, comparable to HD's vascular access creation ($3,000–10,000); however, PD requires less overall investment for home-based care, in contrast to the higher facility setup costs for in-center HD, though PD involves ongoing expenditures for disposable supplies like dialysate bags. In the United States, reimbursement is integrated into the End-Stage Renal Disease (ESRD) Prospective (PPS), which bundles most services into a base rate of US$273.82 per treatment for calendar year 2025, up from US$271.02 in 2024, including add-ons for training up to 15 sessions at US$95.60 each. This bundled approach incentivizes efficient home-based care but has faced challenges from disruptions, such as the 2024 plant closure due to Hurricane Helene, with shortages of PD fluids ongoing into 2025 and phased production recovery (e.g., second manufacturing line restarted by November 2024), leading to increased allocation pressures and potentially raising effective costs by 10–20% through emergency imports and rationing. In , -first policies in countries like , , and promote cost savings of 20–30% compared to , with monthly PD costs at US$1,050 versus US$1,550 for in higher-income Asian settings, driven by government subsidies and reduced hospitalization needs. PD demonstrates strong cost-effectiveness, particularly in LMICs, where it yields incremental cost-effectiveness ratios (ICERs) below US$10,000 per quality-adjusted life year (QALY) gained relative to HD, attributed to early QALY improvements from home-based flexibility and 20–40% lower hospitalization rates. In broader analyses, PD achieves cost savings over HD in the first few years due to avoided clinic visits, with ICERs as low as US$16,934 per QALY in some resource-limited settings, enhancing viability where HD infrastructure is scarce. These advantages are amplified in LMICs, where PD's reduced reliance on specialized facilities contributes to overall healthcare budget efficiencies of up to 25% for ESRD management. The World Health Organization's ongoing prioritization of PD solutions as an essential medicine since 2019 supports these economic benefits by aiming to reduce treatment gaps in resource-limited regions.

Access and Equity

Access to peritoneal dialysis (PD) remains uneven globally, particularly in rural areas where logistical challenges hinder and supply delivery. In low-resource settings, patients often face barriers such as poor road networks, lack of , inadequate , and unreliable to clean water, making it difficult to store and use PD supplies at home. These issues are compounded by long travel distances to clinics for mandatory sessions, exacerbating inequities for rural populations who may otherwise benefit from home-based therapy. Gender disparities further complicate equitable access, as women with frequently shoulder disproportionate caregiving responsibilities, limiting their ability to manage PD independently or receive adequate support. Nephrologists report that social norms around roles create additional hurdles for women, who may prioritize family duties over personal treatment adherence. surrounding home also discourages uptake, with the visible presence of equipment in living spaces leading to social judgment and self-isolation among patients. In communities with high proportions of minoritized groups, such as Latinx populations, cultural against home therapies reinforces preferences for in-center options. Cultural perceptions influence PD acceptance, with higher utilization observed in collectivist societies in where family support aligns well with home-based care requirements. For instance, Hong Kong's long-standing PD-first policy has resulted in an 82% preference for PD among new patients as of 2024, driven by communal caregiving norms and government promotion. The World Health Organization recognized PD solutions as an essential medicine on its complementary list in , aiming to bolster global prioritization and reduce treatment gaps in resource-limited regions. Efforts to enhance equity include PD-first programs in , such as Brazil's urgent-start PD initiative implemented since 2014, which has expanded access by enabling rapid home transitions and addressing hemodialysis shortages, thereby increasing PD utilization among underserved patients. In , ongoing expansions of PD infrastructure seek to overcome human resource shortages and training limitations, promoting broader equity through targeted hospital integrations. Post-2020, telemedicine has emerged as a key tool for remote PD monitoring, improving technique survival and reducing hospitalizations by enabling virtual oversight of and compliance, particularly for isolated patients. Despite these advances, digital divides persist as a 2025 challenge, disproportionately affecting elderly and disabled PD patients who may lack access to devices or for remote monitoring, thus limiting inclusivity in telehealth-supported care. Older adults in low-income or socially deprived areas face heightened exclusion from tools, with studies showing lower engagement due to limited and . This gap undermines PD's potential for independent management among vulnerable groups, highlighting the need for inclusive adaptations like simplified interfaces and community-based support.

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