Microcirculatory dysfunction plays a key role in the pathogenesis of tissue dysoxia and organ failure in sepsis (1). The ultimate goal of resuscitation in septic shock must be the optimization of microvascular blood flow. Systemic hemodynamic parameters, such as cardiac output (CO) and arterial pressure (AP), mixed venous O₂ saturation (SvO₂) or lactate, are usually applied as surrogates of tissue perfusion. Nonetheless, shock is often characterized by a loss of “hemodynamic coherence,” i.e., the concordance between the responses of the macrocirculation and the microcirculation (2): a therapeutic approach that purely targets macro-hemodynamics may thus pose the patients at risk for over- or under-resuscitation. Although a microcirculation-guided approach to the resuscitation of septic patients is desirable (3), important barriers remain for the application of microvascular monitoring alongside the standard hemodynamic parameters.

In this review, we describe the potential role of sublingual videomicroscopy for monitoring the microcirculation and guiding therapy during sepsis, and focus on the obstacles to its widespread use in the daily clinical practice.

Microvascular perfusion is regulated by a complex interplay of neuroendocrine, paracrine and mechanosensory pathways that adapt the local O₂ supply to metabolic needs. These mechanisms are compromised during sepsis, as the inflammatory cascade and oxidative stress lead to endothelial dysfunction (4). The nitric oxide (NO) pathway is severely disturbed with heterogeneous over-expression of the inducible NO synthase and pathological shunting of blood flow in the microcirculation (1). Capillary hemorheology is altered due to a loss of red blood cell (RBC) deformability and tendency to aggregation (4). The endothelial glycocalyx is disrupted, causing capillary leakage, tissue oedema, coagulation abnormalities and enhanced leukocyte-endothelium interaction (5). Heterogeneity in capillary blood flow distribution hampers tissue O₂ extraction, since shunted hypoxic areas occur next to normally or hyper-perfused areas despite preserved total blood flow (6).

The evaluation of the microcirculation has long been limited to the pre-clinical setting (7–9) due to the lack of technologies applicable at the bedside. In 1999, orthogonal polarization spectral (OPS) imaging was introduced and incorporated in a handheld videomicroscope, allowing a non-invasive in vivo observation of flowing RBCs in microvascular beds covered by thin epithelial layers, such as mucosal surfaces (10). De Backer et al. were the first to use OPS in patients with severe sepsis or septic shock and describe a reduction in sublingual microvascular density and the presence of vessels with intermittent or stopped flow (11). Most importantly, these alterations were more severe in non-survivors (11). In the following 20 years, a second generation device, termed sidestream dark field (SDF) (12), and recently a third generation videomicroscope called incident dark field (IDF) (13) were introduced and enabled to obtain images of progressively higher quality, sharper resolution and improved magnification.

Multiple studies used sublingual videomicroscopy to explore sepsis-induced microvascular abnormalities and their relationship with outcome (14–17). Sakr et al. (15) demonstrated that microcirculatory alterations improved rapidly in septic shock survivors, whereas no improvement was observed in patients dying with multiple organ failure, regardless of whether shock had resolved. De Backer et al. (17) found no correlation between the percentage of perfused vessels in the microcirculation and systemic hemodynamic parameters, and microcirculatory alterations were the strongest independent predictors of outcome. Sublingual videomicroscopy also enables to estimate the status of the endothelial glycocalyx by measuring the Perfused Boundary Region (PBR), i.e., the dimension of the permeable part of the glycocalyx allowing the penetration of RBCs (18). The sublingual PBR tended to be higher in septic patients as compared to healthy volunteers or non-septic critically ill patients (18), and a higher PBR was associated with worse outcome (19). The PBR was correlated with the number of rolling leukocytes in the microcirculation, supporting the role of glycocalyx shedding in enhancing leukocyte-endothelium interactions (18). A higher number of adhered leukocytes was found in the sublingual microcirculation of sepsis non-survivors (20).

Resuscitation strategies generally aim to normalize global hemodynamic parameters, with the expectation that this will result in a parallel improvement of tissue perfusion and oxygenation in vital organs. However, this may not happen in cases of sepsis/septic shock in which the “hemodynamic coherence” is lost.

The amount of fluids administered was not correlated with changes in microvascular vessel density during septic shock, whereas the relationship between capillary recruitment and fluid dose was preserved in cardiac surgery patients (21). Fluid administration was able to improve microvascular perfusion within the first 24 h of sepsis but not in a later phase, and the effect was independent of global hemodynamic changes (22). In preload-responsive septic patients, non-linear relationships were found between changes in CO and changes in microvascular perfusion in response to a passive leg raising or a volume expansion, suggesting that different mechanisms are implicated in the macro- and micro-vascular responses (23). In a general ICU population, a fluid challenge improved microcirculatory perfusion only in patients with abnormal microvascular blood flow at baseline, while no effect was observed in those with no significant alterations (24). Again, the microvascular response was independent of changes in stroke volume (24).

Similarly, the microvascular response to vasoactive agents is not straightforward (25). In general, those patients with more severe microvascular alterations are the ones who show a greater improvement in microcirculatory perfusion after the administration of vasoactive medications such as norepinephrine (26) or dobutamine (27), while the mere optimization of macro-hemodynamic parameters (e.g., mean arterial pressure [MAP] or CO) is not sufficient to guarantee a better microvascular blood flow (28). In hypertensive patients, titrating norepinephrine dose to increase MAP from 65 mmHg to usual levels resulted in improved microvascular density and flow (29). In septic shock, the calcium-sensitizer levosimendan improved microvascular perfusion better than 5 mcg/kg*min dobutamine, despite similar macro-hemodynamic effects (30).

As regards blood transfusions, again microvascular perfusion seemed to improve only when significant alterations were present at baseline (31, 32). The type of transfused blood is also important. The transfusion of leukodepleted RBCs might have a favorable effect on microcirculatory flow in sepsis (32). Conversely, the transfusion of old blood (with prolonged storage) may induce an increase in plasma free Hb, which acts as vasoconstrictor (33).

Significant barriers remain for the integration of sublingual microvascular monitoring in the management of septic patients:

- Difficulties in image acquisition and analysis;

Sublingual videomicroscopy is a promising technique for evaluating the microcirculation, i.e., the real interface between blood and cells. For any treatment to be effective in optimizing tissue O₂ availability, it is necessary that microvascular perfusion improves together with macro-hemodynamics. We reviewed the limitations of sublingual microvascular monitoring and the obstacles to its application in the clinical practice, including the lack of specific therapies. Importantly, high-quality clinical trials proving the efficacy of microcirculatory-targeted resuscitation strategies in sepsis are lacking.

Building a feasible and universally effective “microcirculation-centered” treatment algorithm for septic patients is difficult, given the high heterogeneity of sepsis as regards either the patients’ characteristics (e.g., underlying comorbidities), type of infection (e.g., abdominal versus pulmonary), severity of systemic inflammation and circulatory alterations varying over time in response to therapies. In such a complex scenario, the microcirculation could represent a tool for the personalization of therapy. Information coming from sublingual microcirculatory assessment should be part of a comprehensive hemodynamic and physiological monitoring and should be interpreted in the light of other markers of tissue perfusion (Figure 1).

In Figure 2, we propose a hemodynamic optimization algorithm for septic patients, in which microcirculatory monitoring plays a central role together with global hemodynamic parameters. This algorithm is based on three fundamental concepts.

First, we cannot rely purely on macro-hemodynamic targets when trying to restore tissue O₂ delivery in sepsis, since the hemodynamic coherence may be lost. The classical treatments used for the hemodynamic optimization may fail to improve microvascular perfusion and even be deleterious. For example, fluid infusion induces hemodilution and decreases blood viscosity, potentially impairing shear stress-mediated regulation of vascular tone (2). High amounts of fluids in septic shock may cause iatrogenic endothelial injury and glycocalyx degradation (79). Previous studies showed that volume expansion, vasopressors, inotropes and even blood transfusions were able to recruit the microcirculation only if significant alterations were present at baseline, irrespective of the macro-hemodynamic response (24, 26, 27, 31, 32). Therefore, the evaluation of microvascular blood flow should accompany the standard hemodynamic monitoring.

Second, macro- and micro-circulatory responsiveness to treatments should be assessed simultaneously, in order to verify that any improvement in cardiac output or vascular tone results in increased capillary blood flow. Microvascular monitoring may help in guiding fluid, vasopressor and inotrope titration, in order to implement a patient-tailored therapy and avoid any over- or undertreatment. To this aim, it is imperative that technological developments of sublingual videomicroscopy allow an easier and fast assessment of microvascular parameters at the bedside, besides minimizing the possible biases due to poor image quality.

Third, we should consider the possible role of adjunctive therapies (e.g., extracorporeal blood purification) in optimizing microvascular hemorheology (62, 78) and potentially protecting the endothelium from iatrogenic injuries (79).

Bruno et al. very recently evaluated the impact of integrating microvascular monitoring in the therapeutic plan of patients with shock (80). The knowledge of the status of the microcirculation influenced the decision-making process for fluids and vasopressors in a significant number of cases, but had no impact on 30-day mortality (80). Several limitations must be acknowledged: the inclusion of patients with different types of shock (with potentially different microvascular abnormalities), mismatch between the announced and performed treatment changes after microcirculatory evaluation in a substantial number of cases, limitation of life-sustaining therapy in almost half of the patients on day 2, re-assessment of the microcirculation only at 24 h, almost 30% of videos were of unacceptable quality (80). Nonetheless, this was the first large randomized controlled trial on a microcirculation-driven treatment algorithm in patients with shock.

Future studies should be focused on septic shock, exploring the impact of integrating microvascular monitoring in the decision-making process and the efficacy of microcirculation-guided treatment algorithms. Further efforts are needed to find specific therapies for resuscitating the septic microcirculation. In the meantime however, the microcirculation should become part of our clinical reasoning.

ED, AC, EC, RD, CS, AD, and EA: conceptualization. ED: writing – original draft preparation. AC, EC, RD, CS, AD, and EA: writing – review and editing. EA and AD: supervision. All authors contributed to the article and approved the submitted version.