Carbohydrate antigen 125 (CA125) is a glycoprotein synthesized by coelomic epithelial cells in places such as the pleura, pericardium, and peritoneum.16 Although it has traditionally been used for monitoring and risk stratification in ovarian cancer, elevated plasma concentrations of CA125 have been identified in other entities related to hydropic states, such as HF.17 Although the pathophysiological mechanism linked to HF is not fully understood, one of the most accepted theories suggests that there is activation of mesothelial cells in response to increased hydrostatic pressure, mechanical stress, and inflammatory cytokines.18 Recent evidence has shown the association of CA125 with clinical parameters of systemic congestion, and a positive correlation with various surrogate biomarkers of inflammation and congestion.19 Two clinical trials in patients with acute congestive HF have evaluated a diuretic strategy guided by plasma concentrations of CA125 versus standard of care (guided by symptoms and signs) and the results are promising suggesting the usefulness of this biomarker to optimize the intensity of depleting treatment.20,21

Lung ultrasound has emerged as a very useful tool for the evaluation of pulmonary interstitial congestion. The amount of water in the lungs corresponds to the degree of echogenicity found on ultrasound.22 In the case of interstitial pulmonary edema, the ultrasound beam reflects off the edematous interlobar septa and produces reverberation artifacts called B lines.23 The number of B lines is indicative of the degree of pulmonary interstitial congestion. In patients with dyspnea, ≥3 B lines in at least two zones per hemithorax (of 6–8 zones evaluated in total) identifies patients with acute HF with greater sensitivity (94–97%) and specificity (96–97%) than physical examination and chest x-ray.24 Likewise, a higher number of B lines at discharge after hospitalization for acute HF or in outpatients with chronic HF identifies those with a higher risk of HF readmission and death. A recent clinical trial has also shown that pulmonary ultrasound-guided diuretic treatment can reduce the number of decompensations in patients with HF.

Additionally, taking into account the dynamic nature and prognostic relevance of residual congestion,28 integrating clinical parameters, biomarkers and imaging techniques (Appendix A Supplementary material 1) provide relevant information to decision making .29

Acetazolamide acts by inhibiting carbonic anhydrase and thus blocks the reabsorption of bicarbonate and Na+ in the proximal tubule.41 Although the diuretic and natriuretic capacity of acetazolamide on its own is poor, it could play a role as an "enhancer" of diuretic efficacy if used in combination with diuretics that act more distally in the renal tubule by increasing distal delivery of Na+. This concept is supported by small observational studies42–44 and by a small randomized study that included 24 patients with refractory congestion in whom the administration of acetazolamide was associated with an improvement in the fractional excretion of Na+.45

Thus, until the evidence is stronger, acetazolamide is recommended as a second-line drug. Since it can cause metabolic acidosis, periodic evaluation of renal function, serum electrolytes, and blood pH is recommended.

Sodium-glucose cotransporter 2 (SGLT2) inhibitors are hypoglycemic drugs that have been consistently shown to reduce HF hospitalizations in patients with type 2 diabetes mellitus,46 in stable patients with HF and depressed ejection fraction (diabetics and non-diabetics),47 and in diabetic patients with a recent episode of HF regardless of ejection fraction.48

The SGLT2 cotransporter is located in the S1 segment of the proximal convoluted tubule of the nephron and reabsorbs approximately 90% of filtered glucose. Tubular glucose reabsorption is coupled to Na+ reabsorption (one Na+ molecule for each glucose molecule) following an electrochemical gradient of higher concentration in the tubular lumen and lower concentration inside the tubular epithelial cell. In addition, the SGLT2 contransporter is located adjacent to the renal Na+/hydrogen exchanger (NHE3), which is largely responsible for Na+ reabsorption in the proximal tubule. SGLT2 inhibition appears to exert a cross-reaction with the NHE3 exchanger, enhancing natriuresis by a mechanism independent of glucose reabsorption inhibition.49 Although the natriuretic effect of SGLT2 inhibition appears to be weak in monotherapy, recent evidence suggests a synergistic effect when combined with loop diuretics by increasing Na+ delivery to the thick loop of Henle.50 Furthermore, the release of renin mediated by loop diuretics produces an upregulation of the SGLT2 cotransporter, enhancing Na + flow from the proximal tubule to more distal parts after its inhibition.49 Another interesting aspect derives from its potential capacity to produce a significant increase in the excretion of electrolyte-free water, mediated mainly by an osmotic effect.51–53 This effect could favor the decongestion of the interstitium without associating relevant changes in intravascular volume.

Loop diuretics are absorbed relatively rapidly by the gastrointestinal tract (onset of action in 30−60 min). However, the individual bioavailability of oral furosemide varies between 10 and 100% (mean bioavailability of 50%).60 This variation has been attributed to differences in gastric emptying and blood flow, as well as the impact of venous congestion and intestinal edema61 (Fig. 6). In contrast, the absorption and bioavailability of torasemide is more stable (>80%) and is less influenced by intestinal congestion.62 However, dose bioequivalence must be taken into account (40 mg of furosemide is equivalent to 20 mg of torasemide).

Figure 6.

Pharmacokinetic and pharmacodynamic characteristics of furosemide. a) Absorption-dependent kinetics. Furosemide exhibits a unique pharmacokinetic property, the rate of elimination of the drug is significantly faster than the rate of absorption. Therefore, plasma levels are highly dependent on absorption rates, and any impairment in the absorption process leads to significant reductions in the half-life of this agent. b) Postdiuretic sodium retention. Loop diuretics are characterized by short half-lives. Therefore, the initial natriuresis generally decreases progressively in the 3 to 6 h after its administration. During this time, the nephron reabsorbs sodium avidly and can generate a positive balance. c) Natriuretic threshold. The administered dose must exceed a certain threshold to be effective. Thus, it is not surprising that an empirically selected dose may be ineffective. This point is also greatly influenced by the erratic bioavailability of oral furosemide.

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Loop diuretics are characterized by relatively short half-lives. The initial natriuresis generally decreases progressively in the 3–6 h following its administration.63 After this time, the nephron avidly reabsorbs sodium, resulting in “postdiuretic sodium retention”64 (Fig. 6b). In this sense, dosages that maintain stable plasma concentrations would be more recommended in patients with a higher degree of congestion.

The dose administered must exceed a certain threshold to be effective. Although most healthy people will respond to 20 mg of oral furosemide, the natriuresis threshold shifts up and to the right in patients with decompensated HF, even more so if they have concomitant renal dysfunction58,65 (Fig. 6c).

A feature that complicates the effectiveness of diuretic therapy derives from the structure of the nephron itself. Sodium excretion during diuretic therapy reflects a balance between inhibition of reabsorption at the primary site of action and stimulation of reabsorption at other sites in the nephron ("braking phenomenon").66 Although this process is physiological, these mechanisms contribute to diuretic resistance. In addition, chronic treatment with loop diuretics is associated with remodeling and hypertrophy of the distal convoluted and collecting duct, which increases the capacity of the distal nephron to reabsorb sodium and water.

The optimal route of administration of furosemide is not well established. Contiuous infusion offers the theoretical advantage of avoiding the sodium reabsorption peak and reducing sudden changes in intravascular volume.67 Although this strategy has not been shown to reduce rehospitalizations or mortality, a meta-analysis that included a total of 923 patients from 12 studies, observed a greater reduction in weight using this strategy, without being associated with ionic disorders or renal function deterioration.68

The rationale for administering furosemide together with saline resides in its osmotic capacity, which favors vascular refill from the interstitium. This contributes to plasma volume expansion and counteracts the deleterious effect of intravascular depletion caused by diuretics. Clinical trials69–71 and observational studies72–74 in refractory patients have shown its effectiveness in terms of decongestion, preserving renal function, and even reducing adverse events during follow-up. However, there is a wide heterogeneity in the form of preparation and the dose of furosemide used in the different studies (Table 2).

The consensus document on the use of diuretics in patients with HF and congestion of the European Association of Heart Failure 3 places the loop diuretic as the first line of treatment. In addition, in patients admitted for HF who present decreased initial natriuresis or insufficient diuresis, it is recommended to double the dose of loop diuretics up to high doses of furosemide (400−600 mg). This recommendation is based on clinical trials that have evaluated diuretic strategies in acute HF, in which high doses of furosemide were associated with greater resolution of congestion without being associated with adverse events during follow-up.68,68,75,76 (Appendix C Supplemental material 2).

The CARRESS-HF study evaluated veno-venous ultrafiltration vs. a standardized protocol for pharmacological treatment in patients with acute HF and impaired renal function.77 This protocol recommended perfusion of furosemide (10–20 mg/h, preceded by a bolus) and adding a thiazide if the patient continued to have congestion and his daily diuresis was less than 3 L. After evaluating 188 patients, pharmacological treatment was shown to be as effective as veno-venous ultrafiltration in resolving congestion, and produced less deterioration in renal function.

The DOSE-AHF study compared high-dose intravenous furosemide (2.5 times the baseline oral diuretic) vs. low doses (same dose of oral diuretic) in 308 patients with acute HF.75 The high-dose group obtained a greater resolution of the congestive data despite a greater percentage of worsening of renal function. However, a post-hoc analysis showed that this deterioration was associated with fewer adverse events.78

Thiazide diuretics exert their action in the initial part of the distal convoluted tubule, inhibiting the sodium-chloride cotransporter. Although practically 90% of the reabsorption of sodium in patients with HF occurs at a more proximal level,66 in patients treated chronically with loop diuretics there is a greater supply of sodium and a greater avidity for its reabsorption in the distal nephron.

The use of thiazides alone is not very effective in generating natriuresis in patients with HF; however, its addition to treatment with loop diuretics generates a significant increase in fractional excretion of sodium.66 Furthermore, thiazides maintain their natriuretic effect even in the presence of advanced renal failure.79 Observational studies have shown improvement in decongestion when added to furosemide in patients with advanced HF80,81; however, hydro-electrolytic disorders and renal alterations are relatively frequent and may be significant (metabolic alkalosis, hypokalemia, hyponatremia, hypomagnesemia, and renal failure), so these drugs must be used under strict control and monitoring. Hyponatremia occurs because distal natriuresis is greater than the urinary volume excreted, producing hypertonic urine. This same hypochloremic metabolic alkalosis induced by loop and/or thiazide diuretics can generate resistance to their diuretic effect, by mechanisms such as chloride depletion, reduction of drug concentration in tubular lumen and activation of renin.82

The most widely used thiazide diuretics in our environment are chlorthalidone and hydrochlorothiazide. Chlorthalidone has a longer half-life, 45−60 h vs. the 6−15 h of hydrochlorothiazide.3 It should be noted that the natriuretic effect of hydrochlorothiazide is achieved with doses approximately 1.5–2 times higher than those of chlorthalidone.83

There have been no randomized clinical trials that have shown the benefit of thiazides in HF. Intravenous chlorothiazide and metolazone have shown similar efficacy to tolvaptan in a clinical trial on 60 patients with HF and congestion refractory to diuretics, improving diuretic efficiency and generating rapid weight loss.84

Given the experience of using these drugs and their natriuretic potency in combination with loop diuretics, they are usually the treatment of first choice in patients with congestion refractory to high doses of loop diuretics.

The deleterious neurohormonal activation in HF leads to a state of hyperaldosteronism, which is also exacerbated during depletive treatment. At the renal level, aldosterone promotes sodium reabsorption by inducing the expression of epithelial sodium channels in the distal nephron.66

Mineralocorticoid receptor antagonists (MRA) act at the renal level in the distal nephron, inhibiting the effects of aldosterone and therefore modulating the activity and expression of sodium and potassium channels.

Spironolactone and eplerenone are the two most commonly used drugs. Both have been shown to reduce the risk of death and rehospitalization due to HF,85 and have a class I indication in the Clinical Practice Guidelines for the treatment of HF with reduced ejection fraction. However, the doses used in RALES or EMPHASIS-HF (mean daily doses of 26 mg of spironolactone and 40 mg of eplerenone, respectively)85 have little diuretic effect. In patients with HF and preserved ejection fraction, a decrease in physical signs of congestion has been observed with low-dose spironolactone (25 mg/day).86

Spironolactone at doses ≥100 mg/day is capable of inducing natriuresis, improving signs of congestion, and reducing the need for loop diuretics in patients with HF and refractory congestion.87 The main clinical trial that has evaluated the potential benefit of using high doses of MRA was the ATHENA-HF trial, which randomized 360 patients with acute HF to receive spironolactone at a dose of 100 mg daily vs. placebo (or 25 mg/day) for 96 h.88 No differences were observed in NT-proBNP levels (primary endpoint), nor in a combined endpoint of death and HF decompensation events. There were also no differences in secondary surrogate endpoints of diuretic efficacy. It is noteworthy that the drug was used for a short period of time. A pharmacokinetic substudy found that at 48 h many patients receiving the drug de novo had not reached adequate pharmacological levels.89

The main side effect of these drugs is hyperkalaemia,89 and for this reason they can be an especially attractive option in the presence of hypokalaemia.90