Treatment of sepsis-related Acute Respiratory Distress Syndrome with Vasoactive Intestinal Peptide

Purpose: To assess the clinical safety and possible effectiveness of Vasoactive Intestinal Peptide in the treatment of Acute Respiratory Distress Syndrome (ARDS) related to sepsis Methods: Under FDA Investigational New Drug clearance, 8 patients with ARDS related to sepsis were treated with 50 pmole/kg/hr – 100 pmole/kg/hr of Vasoactive Intestinal Peptide by intravenous infusion for 12 hours. All patients were on mechanical ventilation and full telemetery. Results: No drug-related serious adverse events were seen. Hypotension was seen in association with two infusions and diarrhea in association with one, but did not necessitate cessation of therapy. Bigeminy was seen in association with one infusion without sequelae. Seven of eight patients demonstrated a successful course during intensive care and were successfully removed from mechanical ventilation and discharged from intensive care. The eighth patient succumbed to purulent secretions in the lungs. Of those who were discharged from the ICU, six demonstrated successful 30 day survival. The seventh died from a cerebral infract at day 30, deemed unrelated to treatment with VIP. Serum levels of Tumor Necrosis Factor α were obtained in 6 patients at baseline and 24 hours and were seen to decrease with treatment in ve patients. Conclusions: Initial clinical results of treatment with VIP in patients with ARDS demonstrated a safety prole consistent with previous studies in normal volunteers. The successful clinical course seen in 7 of 8 patients in the setting of an expected 50% survival may suggest that VIP shows promise in the treatment of other infectious conditions that damage the pulmonary epithelium, particularly COVID-19. Registration: This clinical trial was registered with www.clinicaltrials.gov under NCT00004494. Trial was registered before the rst patient was enrolled.


Introduction
In March 2020, the US Food and Drug Administration cleared the investigational use of RLF-100 (aviptadil: a synthetic form of Vasoactive Intestinal Peptide (VIP)) for the treatment of Critical  with Respiratory Failure. Among the evidence of human safety included in the Investigational New Drug (IND) application was a previously unpublished study of patients with Acute respiratory distress syndrome (ARDS) in the setting of sepsis. RLF-100 has subsequently been granted a Fast Track Designation by FDA and initial clinical results in the treatment of Critical COVID-19 with Respiratory Failure will shortly be reported. This manuscript reports that prior clinical experience with the use of VIP in ARDS. The results were previously unreported owing to the retirement and subsequent demise of the senior author (SS). However, the clinical course of the treated patients was witnessed by author JGY, who was the primary treating physician for the study.
ARDS is a severe, diffuse in ammatory pulmonary disease with myriad etiologies, for which there is no approved therapy. The underlying condition causes a massive in ammatory response and diffuse edema throughout the lung, culminating in hypoxemia and respiratory distress or failure. Recent mortality estimates for ARDS range from 35-45%, depending on disease severity, with the only accepted therapy being mechanical ventilation. 1 Vasoactive intestinal peptide (VIP) is a ubiquitous neuropeptide throughout the human body. Since its discovery by Said et al. in 1970, (Said 1970, VIP has been identi ed in numerous major organ systems throughout the body. (Power 1988, Onoue 2004, Busto 2000, Feliciano 1998, Fracarroli 2012 but is 70% concentrated in the lung (Virgolini 1995). Within the lung, VIP receptors have primarily been identi ed on Alveolar Type II cells, which are critical to surfactant production (Li 2004) and recycling (Nicholas 1996). VIP also shown to reduce in ammatory cytokines. In vitro and in vivo studies using VIP have demonstrated an immunomodulatory effect, particularly in the setting of acute lung injury. In animal models, VIP downregulates numerous macrophage-mediated in ammatory cytokines as well as known proin ammatory receptors. (Delgado 1999, Ran 2015, Ganea 2015, Hernanz 1996, Ke 2017, Martinez 1998) Moreover, VIP is associated with an increased concentration of anti-in ammatory cytokine IL-10 and promotes the differentiation of Th2 cells in place of proin ammatory T-cell lines. (Wang et al. 2000).
In light of these results, VIP was proposed as a potential treatment for ARDS in 1996, but was not The study originally anticipated recruitment of 16 patients but was terminated after 8 patients as a function of the retirement of the rst author. These results are being published now, after 15 years because of renewed interest in the use of VIP to treat pneumonitis and lung injury associated with COVID-19. The principal investigator of this study (author SIS) is unfortunately deceased. However, the rst author of this publication oversaw the clinical care of the patients in this study.

Methods
Human subjects were treated pursuant to IND 52,088 under a protocol approved by the Institutional Review Board of State University of New York Health Sciences Center, Stony Brook, NY. Patients who met the consensus criteria for diagnosis ARDS in the setting of sepsis were considered for this trial. The trial was registered as NCT00004494 on clinicaltrials.gov. Patients were observed for a 24-h period, during which time all inclusion criteria had to be met. The primary inclusion criteria were sepsis or septic shock, diagnosed ARDS, hypotension, and end organ disfunction. If all criteria had been met once (not necessarily simultaneously), the patient was enrolled and received the study drug over a 12-hour period.
The eligibility criteria for the study were: 1. Acute respiratory failure characterized by: a) hypoxemia, refractory to supplemental 0 2 therapy; b) diffuse pulmonary in ltrates; c) absence of a cardiogenic cause of pulmonary edema; and d) reduced pulmonary compliance. The severity of lung injury in these patients is quanti ed by the scoring system of Murray (Murray 1988).
2. diagnosis of Sepsis/septic shock, characterized by two or more of the following: a. fever or hypothermia (core temp. > 38 o C or <36 o C); tachycardia (heart rate>90, in the absence of B-adrenergic receptor blockade); tachypnea (respiratory rate> 20) or PaCO 2 < 32mm Hg or requirement of mechanical ventilation; white blood cell count >12,000 cells/mm 3 or <4,000 cells/mm 3 or immature neutrophils (bands> 10%); b. Hypotension (systolic blood pressure 90 mm Hg, mean arterial blood pressure < 70 mm Hg, or sustained systolic blood pressure decrease of 40 mm Hg, unresponsive to uid challenge, or the use of vasopressor agents (excluding dopamine at < 5.0 mg/kg per min); c. Evidence of inadequate organ perfusion or organ dysfunction: acute deterioration in mental acuity (excluding edative drugs or other nonseptic causes of altered mental status); or unexplained metabolic acidosis (pH<7.30 or elevated plasma lactate or base de cit of> 5 mEq/L); or oliguria (<0.5 ml/kg/hr) for> 2 h; or unexplained coagulopathy (elevated PT or PTT or platelet count decreased to less than half the baseline value within the past 24 h or <100,000/mm3; or an acute elevation of bilirubin to > 2.0 mg/di and an elevation in one of the liver enzymes (alkaline phosphatase, SGOT, SGPT).

Results
Safety. The objective of this Phase I study was to obtain preliminary data, in an open-label study, on the safety of Aviptadil, infused iv. (50 or 100 pmol/kg/hr, infusion time 6 to 12 hr) in patients with ARDS induced by sepsis. In total, 8 patients were included in the study. Three patients progressed to the high dose group while infusion in the remaining 5 patients was maintained at the lower dose. In 5 cases, there was surgery preceding the infection. Consistent with the polymorbidity of the patients admitted to the trial, they also received a large number of concomitant medications and other supportive measures.
In the lower dose group, Aviptadil administration was stopped in one (bronchial obstruction due to hypersecretion considered to be unrelated to Aviptadil) and the dose halved in another (Hypotension). In the high dose group with 100 pmol/kg/hr (3 patients) Aviptadil administration was stopped in none.
However, dose was transitorily reduced in two, due to hypotension (1 case) or to bigeminy (1 case). Watery stools were observed in one patient in the high dose group.
Two patients died during the long-term follow-up period. Patient # 5, aged 87 years, male, suffered was successfully extubated and discharged from the ICU, but succumbed to a massive right-sided middle cerebral artery infarct three weeks after VIP administration. Supportive measures were stopped at the request of the family. Patient # 2, aged 80 years, male, received the Aviptadil infusion for only 2 of the intended 6 hours because oxygen saturation dropped to 85%. The patient at this point was suctioned from the endotracheal tube and ventilated with an AMBU bag + bronchodilator nebulizer treatment. The endotracheal tube yielded large amount of thick, purulent secretions. The arterial oxygen saturations improved to baseline of 90-92%, but the Aviptadil infusion was not restarted. He died 4 days later; the death was considered a direct consequence of underlying sepsis and unrelated to VIP infusion.  Table 1 gives an overview of the adverse events observed in these severely diseased patients. It is very likely that the adverse events of hypotension and diarrhea are attributable to Aviptadil after IV administration.

Clinical Outcome
Clinical vignettes were available for seven of eight treated patients (see supplemental material).
Examination of patient vignettes reveals multiple comorbidities that are typically seen in patients who develop inpatient sepsis and progress to ARDS. Prior to treatment with VIP, patients received maximum tolerated medical therapy and were on mechanical ventilation. As seen in Table 2, patients had ARDS with moderate to poor prognosis based on PaO 2 / FiO 2 ratio. All patients demonstrated improvement in oxygenation and reduced evidence of respiratory distress (see supplemental material). Seven patients were successfully extubated and discharged from the ICU. The clinical team was encouraged by improvement in the respiratory status of patient MA and believed it to be consistent with survival. However, the underlying neurologic condition in light of the patient's end of life directives caused the family to withdraw consent for further care.

Measurement of TNFα
As an exploratory endpoint, Tissue Necrosis Factor α (TNFα) was measured in 6 of 8 patients. In ve of those patients, a modest decrease in TNFα was seen, while patient #6 demonstrated a substantial increase from baseline (  Although a window of 24-48 h often exists from the time sepsis/septic shock is diagnosed until severe lung and other organ injury occurs, organ injury may develop rapidly and some degree of lung injury may already be present when sepsis is rst diagnosed. By limiting the study population to patients with antecedent or associated sepsis/septic shock excluding those with other risk factors for ARDS such as trauma, drug overdose, acid aspiration, and inhaled toxins, the study group was expected to be more homogeneous and well de ned. The adverse events reported above point to possible side effects of IV-infused VIP. However, the number of cases treated is insu cient and too heterogeneous to draw any conclusions regarding dose dependence or the in uence of comorbidities of these adverse events. However, previous studies in which VIP was administered to humans identi ed similar adverse events. Krejs et al. infused VIP into healthy subjects and reported ushing, increased heart rate, and liquid stools at a dose of 400 pmol/kh/hr. (Krejs et al.) Kane et al. also reported watery diarrhea and subsequent metabolic acidosis within 2-6 hours of VIP infusion for 5 healthy subjects (Kane et al.). A study using inhaled VIP in patients with active sarcoidosis reported mild atulence and loose stools as well as syncope in a small proportion of subjects. (Prasse et al.) All adverse events reported were ameliorated shortly after discontinuing treatment.

Conclusion
Intravenous Vasoactive Intestinal Peptide was generally well-tolerated at doses between 50 -100 pmole/kg/hr in patients treated for ARDS related to sepsis. Although the study was non-randomized, survival was better than expected compared to contemporaneously reported results in this condition. The suggestion of reduced TNFα levels is consistent with nonclinical studies in which VIP was shown to have potent anti-cytokine effects. Based in part on these ndings, synthetic VIP (aviptadil) was cleared by the US FDA in 2020 for investigational use in Critical COVID-19 with respiratory failure.

Declarations Ethics Approval
Human subjects were treated pursuant to IND 52,088 under a protocol approved by the Institutional Review Board of State University of New York Health Sciences Center, Stony Brook, NY.

Consent for publication
No data requiring enhanced consent for publication are included

Availability of Data and Materials
The datasets analyzed during the current study were led with the US FDA and are available from the corresponding author on reasonable request. These data were