Physiology

Instillation of dialysate into the peritoneal space permits diffusion of particles out of the blood and into the fluid across the peritoneum, which acts as a semipermeable membrane. Hypertonic dialysate, causing an osmotic gradient, generates an ultrafiltrate. Water movement will also tend to drag particles across the peritoneum by convection.

Indications

PD can remove excess fluid and provide volume control in patients with oligoanuria. Compared with fluid removal by intermittent hemodialysis, fluid removal with PD is much slower. Manipulation of dialysis fluid osmolality and dwell time can adjust the quantity of volume removed. In hemodynamically unstable, critically ill patients, the slow, steady ultrafiltration achieved with PD may be preferable to the rapid fluid removal that occurs in intermittent hemodialysis.

Similar to volume control, PD provides slow and relatively continuous metabolic control. It is an effective method for correction of uremia. Manipulation of the PD prescription can improve molecular clearance.

Technique

The technique for PD involves instilling a sterile dialysate into the peritoneal cavity and allowing it to dwell for a specified period, during which time diffusion and ultrafiltration occur. At the end of the dwell time, the fluid drains from the peritoneal space and the process repeats.

Flexible, surgically placed catheters are most often used for chronic PD. For acute PD, either this form of catheter or percutaneously inserted temporary PD catheters may be used. Data suggest that fewer complications occur with surgically placed catheters. Catheters come in a variety of sizes, depending on the size of the patient. Local practice often determines who will insert the catheters; the procedure requires expertise to ensure proper catheter function. The International Society for Peritoneal Dialysis recommends a surgically placed Tenckhoff catheter, currently the most used flexible PD catheter.

PD fluid comes in standardized, sterile bags with premixed formulations; pharmacy preparation is usually unnecessary. The solutions consist of electrolytes (sodium, calcium, magnesium), dextrose as the primary osmotic agent, and base (either lactate or bicarbonate). Lactate absorption can lead to confusion in acid–base interpretation, especially in critically ill infants. Bicarbonate-based dialysis fluid may avoid this issue, but premade bicarbonate-based solutions are not available in all countries, requiring extemporaneous preparation by the local pharmacy.

Ultrafiltration in PD occurs by osmotic pressure, usually through the presence of dextrose in the dialysis fluid. Peritoneal dialysate contains standardized concentrations of dextrose; the choices vary somewhat between countries. Dialysate with higher concentrations of dextrose yields greater ultrafiltration for each exchange of fluid.

Peritoneal dialysate should be warmed to body temperature before instillation. This step is particularly important in small patients, in whom cold dialysate infusion can cause hypotension.

Initial exchanges with a new PD catheter should use relatively lower volumes of dialysate (10 to 20 mL/kg; <500 mL/m ² ) to limit the chance of leakage from the catheter exit site. Volumes may increase gradually to 30 to 40 mL/kg or 800 to 1100 mL/m ² .

Longer dwell periods between exchanges provide more time for diffusion and ultrafiltration. Shorter dwell times may not maximize mass transfer for given dwell periods; they may permit more dialysis and ultrafiltration in a 24-hour period by allowing more exchanges per day. Initial dwell periods of 30 to 60 minutes can be adjusted later based on clinical status.

PD fluid can be instilled by hand (manual PD) or with the use of a cycler (automated PD), a device that will automatically fill and empty the patient’s abdomen with dialysate on a preprogrammed schedule. The cycler also contains a warmer for the fluid and monitoring systems to record effluent volumes. Several brands of cyclers are available. Programming limitations may prevent the use of a cycler for some patients who require very small fill volumes or very short dwell times.

When solute clearance or ultrafiltration is suboptimal with conventional PD or the patient cannot tolerate high fill volumes, one may consider the technique of continuous-flow peritoneal dialysis (CFPD). CFPD requires two dialysis catheters placed in the peritoneum, one for inflow and the other for outflow of peritoneal fluid. There is no dwell time per se as the peritoneal fluid is in constant transit through the peritoneum. CFPD can result in a fivefold increase in clearance and a ninefold increase in ultrafiltration. Experience with CFPD is limited; thus, it cannot be considered a standard technique in pediatrics at this time, although it may hold promise in the future.

Disadvantages and complications

The PD technique requires placement of a peritoneal catheter and a sufficiently maintained intraabdominal status to permit infusion of dialysate with successful diffusion and ultrafiltration. Patients who have undergone an abdominal operation or have had abdominal complications may be poor candidates for PD.

Invasion of the peritoneal space puts the patient at risk for peritonitis, a potentially serious complication. The importance of sterile technique when performing PD cannot be overemphasized. Appropriate technique limits, but does not eliminate, the risk of infectious complications, which could be fatal in a critically ill patient.

One must always consider peritonitis in a patient undergoing PD who has a fever or cloudy effluent. Dialysate should be analyzed for cell count, Gram stain, and bacterial culture if infection is suspected. Empirical or specific antibiotics can be placed in the dialysate to treat peritonitis via the intraperitoneal route.

Dialysate can fail to fill or drain through the PD catheter because of a number of potential problems, including kinking of the catheter, fibrin plugs, omental obstruction, and catheter malposition. Percutaneously inserted temporary dialysis catheters are more prone to malfunction than are surgically placed catheters. Abdominal radiographic images can confirm appropriate positioning and permit checks for kinks in the catheter. Some success has been reported with thrombolytic agents to treat fibrin plugging. If simple maneuvers do not correct the malfunction, the catheter may need to be revised or replaced.

Perforation of abdominal or pelvic structures can occur, either at the time of initial catheter placement or later. Although this event is relatively uncommon, significant morbidity can result.

PD is a suboptimal choice for patients who require rapid correction of metabolic abnormalities, immediate removal of circulating toxins, or rapid ultrafiltration for acute complications of fluid overload. For these indications, hemodialysis is preferred. Effectiveness of PD may be suboptimal in settings of low cardiac output with splanchnic circulation compromise. However, this does not preclude the use of PD in selected cases, such as for infants following surgery for congenital heart disease.

Fluid leakage is seen most often with dwell volumes that are too large, especially in the period immediately after catheter placement. Lower fill volumes should be used. Fluid leakage into the thorax can compromise respiration. External fluid leakage around the catheter increases the risk of infection.

Intensive care unit issues

Patients undergoing PD can lose protein into the dialysate. Nutritional support must provide sufficient protein to compensate for this loss. High dextrose concentrations in the dialysate can cause hyperglycemia; administration of insulin may be necessary. Indwelling dialysis fluid causes increased intraabdominal pressure that can complicate care of the critically ill patient. Diaphragmatic excursion may be limited and venous return can be reduced. Stomach compression can lead to gastroesophageal reflux. Although patients undergoing long-term PD who receive fewer daily exchanges usually require maximal fill volumes to achieve adequate dialysis, patients undergoing short-term PD may do better using submaximal fill volumes with more frequent exchanges provided around the clock.

Physiology

The dialyzer used in IHD is an artificial semipermeable membrane. The modern hollow-fiber dialyzer consists of a plastic cartridge traversed by several thousand thin capillary fibers, each with microscopic fenestrations that permit the passage of water and other small molecules. Dialyzers vary in surface area, permeability, priming volume, and membrane composition; numerous dialyzers are available commercially. Choosing different dialyzer characteristics permits adjustment of the dialysis prescription to the clinical situation.

While blood flows through the hollow fibers of the dialyzer, dialysate flows through the cartridge in the space surrounding the fibers. Particles move by diffusion from the blood across the semipermeable membrane into the dialysate. Use of high-flow dialysate with maximal blood flow through the dialyzer permits IHD to remove particles more efficiently than any other RRT.

Increasing blood flow, dialysate flow, or dialyzer size will increase the rate of diffusion. Because diffusion favors the movement of small particles over large particles, large molecules or small molecules bound to larger molecules (such as albumin) will not dialyze well. In addition, intracellular particles will move into the vascular compartment based on individual cell membrane transport characteristics, which may limit the rate at which dialysis can remove particles that do not reside within the vascular compartment.

Ultrafiltration on hemodialysis occurs because of hydrostatic pressure across the membrane that forces water out of the blood. Dissolved particles will travel with the water, leaving by convection. Dialysis staff can control the rate of ultrafiltration with precision and can achieve high rates of ultrafiltration.

Analogous to the process of diffusion, ultrafiltration during IHD removes fluid only from the vascular compartment. Extravascular or third-space fluid must move into the vascular compartment for removal by ultrafiltration. When the rate of movement from the extravascular space is slower than the rate of ultrafiltration, intravascular depletion can occur even though total body water remains elevated ( Fig. 75.3 ). This two-compartment model represents a potential limitation of rapid ultrafiltration during IHD, especially in the critically ill patient.

Two-compartment model of ultrafiltration. The rate of water removal from the vascular compartment by ultrafiltration (large arrows) exceeds the rate of refilling from the extravascular compartment (smaller arrows). This process leads to relative vascular volume depletion and hypotension. BP, Blood pressure.

Indications

Due to its high efficiency, hemodialysis is the best modality for rapid particle removal. IHD is indicated for the treatment of toxic ingestions, many serious drug overdoses, and metabolic derangements that lead to the overproduction of endogenous toxins such as ammonia.

The IHD system can perform ultrafiltration more rapidly than any other renal replacement modality. Consequently, it is often the best choice for the treatment of critical volume overload but may be limited by the patient’s ability to tolerate rapid fluid removal. Technology to guide ultrafiltration by the noninvasive monitoring of hematocrit changes during IHD may prevent or mitigate hypotension associated with ultrafiltration.

Profound metabolic imbalance, such as that seen with critical hyperkalemia, corrects most quickly with IHD. Patients with oncologic problems such as tumor lysis syndrome may require IHD to rapidly correct the multiple metabolic abnormalities and to aid clearance of uric acid, which can cause AKI. ^,

Technique

Vascular access is the first step for successful hemodialysis. Double-lumen catheters for hemodialysis come in a variety of sizes. Occasionally, two single-lumen catheters at separate sites are needed for small infants, although data suggest that these catheters do not perform as well. ^, Catheters can be placed in jugular, femoral, or subclavian positions. The most desirable site for a double-lumen hemodialysis catheter is the right internal jugular vein. It provides access to a high-flow area in the superior vena cava/right atrium, permits a straight venous path from insertion site to target location, can be readily accessed for insertion of either tunneled or nontunneled catheters depending on the indication, allows ambulation and reduces discomfort for the patient as compared with the femoral site, and is less susceptible to complicating venous stenosis that will limit future permanent dialysis vascular access creation (e.g., arteriovenous [AV] fistula). By contrast, subclavian access is associated with increased risk of stenosis that would result in loss of potential sites for AV fistula formation in the ipsilateral arm. In neonates, umbilical catheters have been used if other access has failed. However, umbilical catheters are often not successful due to poor flow dynamics and are not recommended.

Most patients receiving IHD will require anticoagulation therapy to prevent clotting within the dialysis circuit. Any anticoagulant can be used, with goal activated clotting time to be 1.5 to 2 times normal. Unfractionated heparin is the most common anticoagulant for IHD. Some may be able to undergo successful dialysis with little or no heparin because of coagulopathy related to systemic disease. If regional anticoagulation (anticoagulation of the dialysis circuit without systemic effects) is preferred, dialysate containing citrate is available. The citrate in the dialysate will bind calcium locally at the dialyzer membrane, limiting clotting within the dialyzer. Monitoring of ionized calcium is not required as the concentration of citrate is low; thus, the patient is not at risk for hypocalcemia. Clinical experience thus far shows citrate-containing dialysate to be effective as an anticoagulant but some centers find that low-dose systemic heparinization is required.

The blood pump rate depends on the patient’s clinical status and the quality of the vascular access. In smaller patients with smaller catheters, blood pump speeds may be less than 100 mL/min; in infants, speeds may run as low as 25 to 50 mL/min. Larger patients can tolerate faster blood pump speeds. Higher blood flow rates permit greater IHD efficiency.

The chosen dialyzer should provide sufficient clearance to achieve the goals of the dialysis session. Smaller patients receive dialysis with smaller dialyzers to limit extracorporeal blood volume and reduce the risk of dialyzer clotting with slower blood flow rates.

Small patients or those with unstable blood pressure may require priming of the IHD circuit with saline solution, albumin, or reconstituted whole blood. Dialysis machines with precise volumetric ultrafiltration control permit accurate and safe IHD in neonates and infants, for whom small inaccuracies in ultrafiltration volumes could potentially lead to severe fluid imbalances. One may make some adjustments to the electrolyte concentrations in dialysis fluid depending on the clinical situation. The length of the IHD session will vary depending on the clinical situation and goals of the therapy. Mathematical models permit estimation of dialytic clearance and help to structure session length. The rate at which the patient can tolerate ultrafiltration is often the limiting factor in IHD for critically ill patients; one may need to extend the session length to achieve ultrafiltration goals without significant hypotension.

Disadvantages and complications

The principal disadvantage of IHD is the requirement for vascular access. Acceptable access can be difficult to achieve in critically ill children. Complications related to the access can include infection, bleeding, and thrombosis.

IHD’s benefit of high efficiency with rapid fluid and particle removal can lead to difficulties in the ICU setting. Critically ill patients may not tolerate the rapid ultrafiltration and metabolic shifts of IHD.

Smaller patients or those with unstable blood pressure may require priming of the extracorporeal circuit to limit hemodynamic stress at dialysis initiation. For infants in whom the extracorporeal volume is relatively much larger, priming may require a blood/albumin mix, which exposes the patient to blood products.

Most IHD sessions require systemic anticoagulation with heparin, which can be difficult to manage in a critically ill child. Heparin exposure can complicate bleeding and cause heparin-induced thrombocytopenia. With careful monitoring of clotting times and circuit performance during the session, it is possible to perform IHD without anticoagulation. Regional anticoagulation is also available with dialysate containing citrate.

Intensive care unit issues

Patients receiving IHD as ongoing RRT in the ICU require special attention to fluid and electrolyte balance. One should limit potassium and phosphorus delivery and may need to limit total daily fluids because ultrafiltration occurs only intermittently. Administer blood during dialysis to remove excess potassium. Medication doses and schedule may require adjustment because of poor excretion with renal failure and subsequent rapid removal with dialysis.

Physiology

The CRRT hemofilter is similar to that used for IHD. CRRT membranes traditionally have been more porous to permit greater removal of water. Numerous hemofilters are available commercially.

CRRT may employ both convection and diffusion. Dialysate allows diffusion, which favors the movement of smaller molecules. High rates of ultrafiltration will remove both small and larger particles by convection, up to the limits of the membrane. With high ultrafiltration rates to achieve better convective clearance, the patient may need to receive replacement of volume and electrolytes to compensate for that lost in ultrafiltrate.

Because of slower flow rates, clearance with CRRT may be lower than IHD. Continuous therapies make up for this lower efficiency through the extended treatment time. Compared with a 3- or 4-hour IHD session, CRRT running 24 hours a day can achieve equivalent daily clearance with less metabolic variation. Newer CRRT devices can run at flow rates approaching those seen in IHD, greatly increasing the potential for rapid molecular clearance.

Nomenclature for the subcategories of CRRT derives from the vascular access and primary method of particle clearance (convection, diffusion, or both). Because most CRRT in pediatric patients uses a pump-assisted venovenous method, the most commonly used terms are continuous venovenous hemofiltration (CVVH), which uses high convective clearance requiring replacement fluids; continuous venovenous hemodialysis (CVVHD), which uses dialysis fluid for diffusion but minimal additional convection; and continuous venovenous hemodiafiltration (CVVHDF), which uses both dialysis fluid and replacement fluids for combined diffusion and high-grade convection.

Indications

CRRT is particularly well suited to the treatment of volume overload in critically ill patients. Whereas IHD will attempt to reach an ultrafiltration goal within a relatively short therapeutic session, CRRT allows continuous ultrafiltration that can help maintain cardiovascular stability.

CRRT is useful to maintain metabolic balance through ongoing removal of unwanted particles. Although it is less efficient than IHD, CRRT’s continuous nature can avoid daily fluctuations inherent in the use of an intermittent modality. In addition, CRRT can maintain metabolic balance after rapid correction with IHD.

For patients with diminished renal function and decreased urinary output, CRRT allows administration of the daily load of fluids and clearance required to deliver medication, nutrition, and blood products. With this modality, the patient can be maintained in a more stable balance compared with IHD, in which the patient has progressive volume overload between IHD sessions and then must achieve the ultrafiltration goal in a brief treatment period.

Technique

As in IHD, successful CRRT requires adequate vascular access. Given the relatively large extracorporeal volume, smaller patients may require priming of the CRRT circuit with blood/albumin mix. Larger, more stable patients may initiate CRRT with saline prime.

Several CRRT systems are available at this time. The latest generation of CRRT machines permits much greater accuracy for blood pump speed, fluid delivery, and ultrafiltration control.

Disadvantages and complications

Like IHD, CRRT requires vascular access, which can be difficult to obtain in infants and small children. Data suggest that 5 Fr single-lumen catheters should not be used for CRRT because they are associated with significantly shorter functional CRRT circuit survival. Continuous extracorporeal perfusion and anticoagulation carry risks of bleeding and infection. Some patients experience blood pressure instability despite the slow method of ultrafiltration. Continuous exposure to heparin can lead to heparin-induced thrombocytopenia. Patients receiving citrate anticoagulation are at risk for acid–base disturbance or hypocalcemia. Citrate excess can cause low patient ionized calcium with normal or high total calcium levels, the so-called calcium gap or citrate lock , ^, which occurs when excess citrate binds free calcium in the patient. Under these circumstances, one may reduce citrate delivery or increase CRRT clearance.

Intensive care unit issues

Continuous clearance on CRRT, particularly with convective modalities, can cause profound electrolyte deficiencies requiring replacement. Similarly, nitrogen losses on CRRT can be high. Patients require increased nutritional support during CRRT therapy with careful consideration of the nutritional prescription. Medication dosages often require adjustment because of CRRT clearance. Coordination between the ICU staff and nephrology staff is essential to establish appropriate goals for fluid removal and metabolic control.

Extended dialysis

One may extend IHD sessions to provide therapy that approaches CRRT. Variously referred to as slow low-efficiency dialysis or slow extended daily dialysis, such techniques can provide improved molecular clearance with better tolerance of ultrafiltration when compared with conventional schedules for IHD. Sessions may run 6 to 8 hours or more on a daily basis.

Some institutions may prefer extended dialysis methods because they obviate the need to purchase and maintain separate dedicated CRRT equipment, using instead standard IHD machines that have been adapted for longer session length. In addition, disposable materials are usually less expensive than for CRRT, potentially leading to cost savings. Online generation of dialysate, as for standard IHD, greatly simplifies solution delivery compared with premixed bags that must be frequently exchanged for CRRT. However, most online dialysate is not sterile, raising a theoretic risk for the critically ill patient. Newer devices capable of extended therapies can be adapted to provide ultrapure dialysis fluid, which may mitigate this potential concern.