A randomized controlled trial of treatment with intermittent negative pressure for intermittent claudication.

OBJECTIVE: We investigated the effects of lower extremity intermittent negative pressure (INP) treatment for 1 hour two times daily for 12 weeks on the walking distance of patients with intermittent claudication (IC). METHODS: Patients with IC were randomized to treatment with -40 mm Hg INP (treatment group) or -10 mm Hg INP (sham control group). Pain-free walking distance (PWD) and maximal walking distance (MWD) on a treadmill, resting and postexercise ankle-brachial index, resting and postischemic blood flow (plethysmography), and quality of life (EQ-5D-5L and Vascuqol-6) were measured at baseline and after 12 weeks of treatment. RESULTS: A total of 72 patients were randomized, and 63 had data available for the intention-to-treat analyses. The between-group comparisons showed a significant change in the PWD, favoring the treatment group over the sham control group (estimated treatment effect, 50 m; 95% confidence interval [CI], 11-89; P = .014). The PWD had increased by 68 m (P < .001) in the treatment group and 18 m (P = .064) in the sham control group. No significant difference was found in the change in the MWD between the two groups (estimated treatment effect, 42 m; 95% CI, -14 to 97; P = .139). The MWD had increased by 62 m (P = .006) in the treatment group and 20 m (P = .265) in the sham control group. For patients with a baseline PWD of <200 m (n = 56), significant changes had occurred in both PWD and MWD between the two groups, favoring the treatment group (estimated treatment effect, 42 m; 95% CI, 2-83; P = .042; and estimated treatment effect, 62 m; 95% CI, 5-118; P = .032; respectively). Both overall and for the group of patients with a PWD <200 m, no significant differences were found in the changes in the resting and postexercise ankle-brachial index, resting and postischemic blood flow, or quality of life parameters between the two groups. CONCLUSIONS: Treatment with -40 mm Hg INP increased the PWD compared with sham treatment in patients with IC. For the patients with a baseline PWD of <200 m, an increase was found in both PWD and MWD compared with sham treatment.

Mobile Lower Body Negative Pressure Suit as an Integrative Countermeasure for Spaceflight.

BACKGROUND: Persistent headward fluid shift and mechanical unloading cause neuro-ocular, cardiovascular, and musculoskeletal deconditioning during long-term spaceflight. Lower body negative pressure (LBNP) reintroduces footward fluid shift and mechanical loading.METHODS: We designed, built, and tested a wearable, mobile, and flexible LBNP device (GravitySuit) consisting of pressurized trousers with built-in shoes to support ground reaction forces (GRF) and a thoracic vest to distribute load to the entire axial length of the body. In eight healthy subjects we recorded GRF under the feet and over the shoulders (Tekscan) while assessing cardiovascular response (Nexfin) and footward fluid shift from internal jugular venous cross-sectional area (IJVa) using ultrasound (Terason).RESULTS: Relative to normal bodyweight (BW) when standing upright, increments of 10 mmHg LBNP from 0 to 40 mmHg while supine induced axial loading corresponding to 0%, 13 ± 3%, 41 ± 5%, 75 ± 11%, and 125 ± 22% BW, respectively. Furthermore, LBNP reduced IJVa from 1.12 ± 0.3 cm² to 0.67 ± 0.2, 0.50 ± 0.1, 0.35 ± 0.1, and 0.31 ± 0.1 cm², respectively. LBNP of 30 and 40 mmHg reduced cardiac stroke volume and increased heart rate while cardiac output and mean arterial pressure were unaffected. During 2 h of supine rest at 20 mmHg LBNP, temperature and humidity inside the suit were unchanged (23 ± 1°C; 47 ± 3%, respectively).DISCUSSION: The flexible GravitySuit at 20 mmHg LBNP comfortably induced mechanical loading and desired fluid displacement while maintaining the mobility of hips and knee joints. The GravitySuit may provide a feasible method to apply low-level, long-term LBNP without interfering with daily activity during spaceflight to provide an integrative countermeasure.Petersen LG, Hargens A, Bird EM, Ashari N, Saalfeld J, Petersen JCG. Mobile lower body negative pressure suit as an integrative countermeasure for spaceflight. Aerosp Med Hum Perform. 2019; 90(12):993-999.

Construction of a lower body negative pressure chamber.

Lower body negative pressure (LBNP) is an established and important technique used to physiologically stress the human body, particularly the cardiovascular system. LBNP is most often used to simulate gravitational stress, but it has also been used to simulate hemorrhage, alter preload, and manipulate baroreceptors. During experimentation, the consequences of LBNP and the reflex increases in heart rate and blood pressure can be manipulated and observed in a well-controlled manner, thus making LBNP an important research tool. Numerous laboratories have developed LBNP devices for use in research settings, and a few devices are commercially available. However, it is often difficult for new users to find adequately described design plans. Furthermore, many available plans require sophisticated and expensive materials and/or technical support. Therefore, we have created an affordable design plan for a LBNP chamber. The purpose of this article was to share our design template with others. In particular, we hope that this information will be of use in academic and research settings. Our pressure chamber has been stress tested to 100 mmHg below atmospheric pressure and has been used successfully to test orthostatic tolerance and physiological responses to -50 mmHg.

Ambulation in simulated fractional gravity using lower body positive pressure: cardiovascular safety and gait analyses.

The purpose of this study is to assess cardiovascular responses to lower body positive pressure (LBPP) and to examine the effects of LBPP unloading on gait mechanics during treadmill ambulation. We hypothesized that LBPP allows comfortable unloading of the body with minimal impact on the cardiovascular system and gait parameters. Fifteen healthy male and female subjects (22-55 yr) volunteered for the study. Nine underwent noninvasive cardiovascular studies while standing and ambulating upright in LBPP, and six completed a gait analysis protocol. During stance, heart rate decreased significantly from 83 +/- 3 beats/min in ambient pressure to 73 +/- 3 beats/min at 50 mmHg LBPP (P < 0.05). During ambulation in LBPP at 3 mph (1.34 m/s), heart rate decreased significantly from 99 +/- 4 beats/min in ambient pressure to 84 +/- 2 beats/min at 50 mmHg LBPP (P < 0.009). Blood pressure, brain oxygenation, blood flow velocity through the middle cerebral artery, and head skin microvascular blood flow did not change significantly with LBPP. As allowed by LBPP, ambulating at 60 and 20% body weight decreased ground reaction force (P < 0.05), whereas knee and ankle sagittal ranges of motion remained unaffected. In conclusion, ambulating in LBPP has no adverse impact on the systemic and head cardiovascular parameters while producing significant unweighting and minimal alterations in gait kinematics. Therefore, ambulating within LBPP is potentially a new and safe rehabilitation tool for patients to reduce loads on lower body musculoskeletal structures while preserving gait mechanics.

Intra-abdominal pressure may be decreased non-invasively by continuous negative extra-abdominal pressure (NEXAP).

OBJECTIVE: To investigate the possibility of artificially decreasing intra-abdominal pressure (IAP) by applying continuous negative pressure around the abdomen. MATERIAL AND METHODS: We investigated the effects of negative extra-abdominal pressure (NEXAP) on IAP and central venous pressure (CVP) in 30 patients admitted to our intensive care unit (age 57+/-17 years, BMI 26.1+/-4.0 kg/m2, SAPS II 41.8+/-17.0). Patients with severe hemodynamic instability and/or those admitted following a laparotomy were not studied. Measurements included bladder pressure as an estimate of IAP, CVP, invasive mean arterial pressure (MAP) and heart rate (HR). In five patients extensive hemodynamic measurements were also taken using a Swan-Ganz catheter. Following measurements at baseline (Basal), NEXAP (Life Care - Nev 100, Respironics) was applied on the abdomen, in random order, at a pressure equal to IAP (NEXAP0), 5 cmH(2)O (NEXAP-5) or 10 cmH(2)O (NEXAP-10) more negative than NEXAP0. RESULTS: Basal IAP ranged from 4 to 22 mmHg. NEXAP decreased IAP from 8.7+/-4.3 mmHg to 6+/-4.2 (Basal vs NEXAP0 p<0.001). There was a further decrease of IAP when more negative pressure was applied: 4.3+/-3.2 mmHg, 3.8+/-3.7 mmHg (NEXAP-5 and NEXAP-10 vs NEXAP0, respectively, p<0.001). Similarly, CVP decreased from 9.3+/-3.4 mmHg to 7.5+/-3.8 (Basal vs NEXAP-10, p<0.001). The lower the IAP when NEXAP was applied, the lower the CVP (r2=0.778, p<0.001, multiple linear regression). When measured, cardiac output did not significantly change with NEXAP. CONCLUSIONS: Negative extra-abdominal pressure may be applied in critically ill patients to decrease intra-abdominal pressure non-invasively.

Use of lower body negative pressure to counter symptoms of orthostatic intolerance in patients, bed rest subjects, and astronauts.

This report briefly discusses some aspects of autonomic cardiovascular dysfunction as related to changes in orthostatic function in patients, bed rest subjects, and astronauts. This relationship is described in normal individuals to provide the basis for discussion of parameters that may be altered in patients, bed rest subjects, and astronauts. The relationships between disease states, age, periods of weightlessness during space flight, and autonomic dysfunction, and their contribution to changes in orthostatic tolerance are presented. The physiologic effects of lower body negative pressure are illustrated by presenting data obtained in bed rest subjects and in astronauts. Finally, the usefulness of lower body negative pressure to counter symptoms of orthostatic intolerance in patients, bed rest subjects, and astronauts is discussed.

Applied potential tomography shows differential changes in fluid content of leg tissue layers in microgravity.

Absence of hydrostatic forces in the human cardiocirculatory system normally leads to an overall body fluid deficit. It was hypothesized that this is mainly due to a loss of interstitial fluid. An experiment was performed on board the Russian MIR station. Cuffs were positioned around both thighs and inflated up to suprasystolic values. This maneuver took place just before and after immediately a lower body negative pressure session (LBNP). The redistribution of fluids underneath the cuffs was assessed by means of cross-sectional impedance tomography (Applied Potential Tomography, APT). A microgravity induced loss of interstitial fluid was measured in all layers of the observed cross-section. The APT-readings changed significantly (SD approximately +/- .9) from 3.0 at 1g to 1.7 at 0g for the outer layer and from 2.7 at 1g to 2.0 at 0g for the middle layer (expressed in arbitrary units). The LBNP maneuver was able to fill the interstitial space but only at levels higher than -15 mmHg LBNP. This suggests that the superficial tissues in the legs are as much affected as the deeper ones by changing g-conditions and LBNP can be used to counteract interstitial fluid loss in this area.

Lower body negative pressure box for +Gz simulation in the upright seated position.

The cost of purchasing and operating a human centrifuge is substantial. Lower body negative pressure (LBNP) is considered an acceptable experimental substitute for the +Gz stress of the centrifuge. Since civil aviation pilots are usually subjected to +Gz stress in an upright seated position, an upright seated version of the supine LBNP box was developed. In this version, a negative pressure of -40 torr is considered the equivalent of a 2 +Gz stress. This box has successfully withstood a test pressure of -120 torr. Pedal ergometry within the box is easily accomplished. The box was anthropometrically engineered to accommodate a human height range of 160-195 cm. Locating the box within an altitude chamber allows the application of LBNP at any level of chamber altitude. The total cost of fabrication is approximately $500.

Self-generated lower body negative pressure exercise.

BACKGROUND: Exercise during spaceflight helps prevent musculoskeletal and cardiovascular deconditioning to Earth gravity. This report evaluates the aerobic and anaerobic exercise stimulus provided by self-generated lower body negative pressure. METHODS: A lower body negative pressure cylinder expands and collapses longitudinally, but not radially. As the legs push footward to expand the cylinder, the air pressure in the cylinder decreases, increasing the force required to continue expanding the cylinder. In addition, valves control air flow into and out of the cylinder, and thus workload. In seven supine subjects, knee bend exercise was performed at 19 cycles per minute for 6 min. Footward force was measured with load cells, cylinder pressure with a transducer, heart rate from ECG, and oxygen consumption with turbine volumetry and gas analysis. RESULTS: Maximum footward force at the peak of the exercise cycle averaged 1120+/-88 N (114+/-9 kg), and pressure within the cylinder concomitantly decreased 26+/-3 mmHg below ambient. Heart rate and oxygen consumption increased 75+/-4 bpm and 26.3+/-1.4 ml O2/kg x min(-1) from supine resting values, respectively. CONCLUSIONS: With the air inlet valve nearly closed, exercise with this device approximates a resistance-type leg press. With more inflow of air, more rapid, aerobic knee bends can be performed. This exercise device/concept provides simultaneous dynamic musculoskeletal and cardiovascular stresses without an external power source.

Nursing care for raised intra-abdominal pressure and abdominal decompression in the critically ill.

Abdominal assessment is one of a number of continuous assessments that critical care nurses undertake. Since 1988 in the Department of Critical Care Medicine (DCCM), the technique of abdominal decompression has become another therapy for severe critical illness. The critical care nurse requires to have an understanding of raised intra-abdominal pressure assessment, pressure measurement and the care of abdominal polypropylene mesh insertion in the critical care setting. Our experience has been that the use of polypropylene mesh insertion halved since 1993. A retrospective study (Torrie et al. 1996) of 68 occasions (64 patients) of polypropylene mesh insertion, showed that seven patients developed fistulas and 32 patients died. There was no dehiscence of the mesh from the fascia. Forty-two wounds had primary fascial closure (28 with primary skin closure, 3 with secondary skin closure, 11 left to granulate) and 3 of them later dehisced. At follow-up (27 patients, median 7.5 months), 6 had stitch sinuses, and 5 had incisional hernias. Care of patients with polypropylene mesh inserted requires vigilant nursing practice but decompression of raised intra-abdominal pressure can be life-saving and complications are manageable.

[The effect of local decompression on ovarian function in women operated on for benign epithelial tumors of the ovaries]. / Vliianie lokal'noi dekompressii na funktsional'noe sostoianie iaichnikov zhenshchin, operirovannykh po povodu dobrokachestvennykh épitelial'nykh opukholei iaichnikov.

Mathematical modelling led the authors to the conclusion that local abdominal-vaginal decompression in females operated on for BETO contributes to recovery of functional relations between hormone production by the ovaries, protease-protease inhibitors system, vascular system of the ovaries. It is the impairment of this relationship that is responsible for postoperative complications. Local decompression is recommended as a beneficial physical factor in combined rehabilitation of BETO females.

Temporary abdominal vacuum-packing closure in the neonatal intensive care unit.

BACKGROUND: Temporary abdominal vacuum-packing (vac-pac) closure is well known in adult literature, yet has not been reported in infants. METHODS: A review of children in the neonatal intensive care unit who underwent vac-pac closure from 2000 to 2006 was performed. RESULTS: During this time, 7 infants underwent vac-pac closure after abdominal surgery. Median age was 39 days, with a median weight of 3.2 kg. Reasons for vac-pac included abdominal compartment syndrome (3), ongoing intraabdominal sepsis (1), anticipated second-look procedures (2), and abdominal observation after repair of congenital diaphragmatic hernia on extracorporeal membrane oxygenation (1). PaCO2 revealed a drop from a median preoperative level of 50.3 to 44.0 mm Hg postoperatively. Median preoperative urine output was 3.9 and 3.1 mL/(kg h) postoperatively. One patient died with an open abdomen from overwhelming Escherichia coli sepsis, and all surviving patients (85.7%) proceeded to definitive abdominal closure with the median time of vac-pac use being 4 days. CONCLUSION: Vac-pac closure in infants is a safe and effective method of temporary abdominal closure. The detrimental effects of intraabdominal hypertension as well as risk of hemorrhage after repair of congenital diaphragmatic hernia while on extracorporeal membrane oxygenation also make this an important technique for abdominal observation.

European isolation and confinement study. Lower body negative pressure tests.

From the LBNP experiment carried out during the ISEMSI project, we can conclude that there was no indication of the cardiac deconditioning syndrome in any of the six subjects. The absence of such effects can probably be ascribed to the following two conditions: (1) the subjects were not in inactive conditions; and (2) there was only a slight overpressure in the hyperbaric chamber.

[Abdominal decompression - should this obstetric method be employed in future too? (author's transl)]. / Ist die Abdominal Decompression ein Verfahren, welches in der Geburtshilfe noch Anwendung finden soll?

Heyns developed a method to produce decompression in the abdomen of pregnant women. He stated that the method was recommended to promote analgesia during the period of dilatation and to shorten the delivery period. Since enhanced blood supply of the placenta was expected also, the method was stated to be useful in gestosis patients. Regular application during the last three months of pregnancy were said to enhance the intelligence of the foetus. The examinations quoted in this article show insufficient analgesia and lack of shortening of the delivery period. No clear evidence of increased placental blood supply was seen. On account of the uncomfortable mode of application and the hypovolaemic sequential condition this method has not been accepted as obstetric practice.