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Peritoneal fluid

Peritoneal fluid is a serous liquid secreted by the mesothelial cells lining the peritoneum, the thin serous membrane that envelops the abdominal cavity and covers most intra-abdominal organs.^[1] This fluid occupies the potential space between the parietal peritoneum (which lines the abdominal walls) and the visceral peritoneum (which wraps around the organs), providing essential lubrication to facilitate smooth movement of these structures during respiration, digestion, and other physiological activities.^[2] In healthy adults, the volume of peritoneal fluid typically ranges from 5 to 100 milliliters, maintaining a delicate balance through continuous production and absorption.^[3] The composition of peritoneal fluid resembles an ultrafiltrate of plasma, containing water, electrolytes, low levels of proteins (such as albumin and immunoglobulins), and cellular components including macrophages, lymphocytes, and mesothelial cells.^[3] These elements enable the fluid to serve not only as a lubricant but also as a physiological barrier against infection, supporting immune surveillance and selective transport of solutes and cells across the peritoneal membrane.^[3] Absorption occurs primarily through lymphatic stomata located in the diaphragmatic peritoneum, where diaphragmatic contractions during breathing propel the fluid into lymphatic vessels and ultimately the thoracic duct, ensuring homeostasis.^[3] Clinically, peritoneal fluid plays a key role in diagnostics and therapeutics; its analysis via paracentesis can reveal abnormalities indicative of infection (peritonitis), inflammation, malignancy, or portal hypertension.^[2] Pathological accumulation of this fluid, known as ascites, is most commonly associated with liver cirrhosis, heart failure, or peritoneal carcinomatosis, affecting up to 50% of patients with advanced cirrhosis.^[4] In renal failure, the peritoneum's semipermeable properties allow peritoneal fluid to be utilized in dialysis, where dialysate is introduced to remove waste products from the bloodstream.^[2]

Anatomy

Peritoneal Cavity

The peritoneal cavity is a potential space within the abdominal and pelvic regions, formed between the parietal and visceral layers of the peritoneum, and it normally contains a thin film of serous fluid that facilitates lubrication between adjacent structures.^[1] This cavity encompasses the majority of the abdominal contents and serves as the site for intraperitoneal organs, while excluding retroperitoneal structures.^[1] The boundaries of the peritoneal cavity define its extent: superiorly, it is limited by the diaphragm; inferiorly, by the pelvic floor; anteriorly, by the abdominal wall; and posteriorly, by retroperitoneal structures such as the vertebrae, kidneys, and major vessels.^[1] These boundaries create a closed compartment that separates the peritoneal contents from surrounding tissues, with the cavity extending from the diaphragm down to the pelvic inlet.^[1] The peritoneal cavity is subdivided into the greater sac, which forms the main expansive portion surrounding most abdominal organs, and the lesser sac, also known as the omental bursa, a smaller recess located posterior to the stomach.^[1] These subdivisions communicate via the epiploic foramen (foramen of Winslow), a narrow passage bordered anteriorly by the hepatoduodenal ligament, posteriorly by the inferior vena cava, inferiorly by the duodenum, and superiorly by the caudate lobe of the liver.^[1] In terms of organ relations, the peritoneal cavity directly surrounds intraperitoneal organs, which are enveloped by the visceral peritoneum and include the stomach, liver, spleen, jejunum, ileum, and transverse and sigmoid colon.^[1] In contrast, retroperitoneal organs such as the kidneys, pancreas, duodenum (parts 2–4), aorta, and ureters lie outside the cavity, posterior to the parietal peritoneum.^[1] Embryologically, the peritoneal cavity originates from the coelomic cavity in the early embryo, which forms a continuous space surrounding the primitive gut tube. The coelomic cavity develops from the splitting of the lateral plate mesoderm into somatic and splanchnic layers.^[5] This coelomic cavity undergoes partitioning during fetal development to separate into distinct peritoneal, pleural, and pericardial compartments, with the peritoneal portion establishing the adult abdominal space.^[5]

Peritoneum

The peritoneum is a serous membrane that lines the walls of the abdominal and pelvic cavities and envelops many of the abdominal organs, serving as a protective barrier and structural framework. It consists of a monolayer of flattened mesothelial cells resting on a thin basement membrane, supported by an underlying layer of loose connective tissue rich in collagen and elastin fibers. These mesothelial cells, derived from mesodermal origin, form a simple squamous epithelium that facilitates selective permeability and barrier functions.^[1]^[6] The peritoneum is divided into two primary layers: the parietal peritoneum, which adheres directly to the inner surfaces of the abdominal wall and pelvis, and the visceral peritoneum, which directly covers the surfaces of intraperitoneal organs such as the stomach, liver, and intestines. The parietal layer is innervated by somatic nerves from the lower thoracic and lumbar spinal segments (T10-L1), enabling precise localization of pain and temperature sensations, while the visceral layer receives autonomic innervation via the vagus nerve and sympathetic fibers, resulting in more diffuse visceral sensations. Specialized peritoneal folds, including mesenteries (e.g., the mesentery proper attaching the jejunum and ileum to the posterior abdominal wall), omenta (greater omentum draping from the stomach over the intestines and lesser omentum connecting the stomach to the liver), and ligaments (e.g., the falciform ligament anchoring the liver to the anterior abdominal wall), extend between organs and the body wall to provide support, mobility, and pathways for neurovascular structures.^[1]^[1]^[1] The blood supply to the peritoneum arises from branches of the abdominal aorta, with the visceral peritoneum primarily fed by the celiac trunk, superior mesenteric artery, and inferior mesenteric artery, while the parietal peritoneum receives contributions from intercostal, lumbar, epigastric, and iliac arteries. Venous drainage from the visceral layer converges into the portal vein system, whereas the parietal layer drains into the inferior vena cava. Lymphatic drainage follows the vascular pathways through submesothelial lymphatics and mesenteric nodes, ultimately collecting into the cisterna chyli at the base of the thoracic duct for return to the systemic circulation.^[7]^[7]^[8] Histologically, the peritoneal surface is characterized by a continuous layer of simple squamous mesothelial cells, which are polygonal or cuboidal in shape and connected by tight junctions, overlying a submesothelial connective tissue layer containing fibroblasts, macrophages, and other immune cells embedded in an extracellular matrix of collagen and proteoglycans. This submesothelial zone varies in thickness but typically includes capillaries, small venules, and lymphatic vessels that support nutrient exchange and fluid dynamics. The mesothelial cells contribute to the production of a thin serous fluid layer that lubricates organ movement within the cavity.^[6]^[9]^[9]

Physiology

Production and Absorption

Peritoneal fluid is produced through the ultrafiltration of plasma across the endothelial walls of capillaries embedded in the submesothelial connective tissue of the peritoneum. This filtration process is governed by Starling forces, where the hydrostatic pressure gradient from the capillaries drives fluid out, balanced against the opposing oncotic pressure exerted by plasma proteins.^[10] Production primarily occurs from the capillary networks in the diaphragmatic peritoneum and omentum, contributing to the thin serous layer that lubricates abdominal structures.^[11] Absorption of peritoneal fluid predominantly takes place via the lymphatic system, with fluid entering specialized stomata—small openings in the mesothelial layer of the diaphragmatic peritoneum—that connect directly to underlying lymphatic lacunae and subpleural lymphatics.^[10] Diaphragmatic contractions during respiration close these stomata and propel fluid into the lymphatics for transport via the thoracic duct to the venous circulation. A secondary pathway involves venous reabsorption through adjacent peritoneal tissues, also mediated by local Starling forces. In normal adults, the lymphatic absorption rate is approximately 0.3 mL/min, equivalent to about 400–500 mL per day.^[12]^[13] These processes are tightly regulated by hydrostatic and oncotic pressure gradients across the peritoneum. The overall turnover is rapid, with instilled fluid dispersing and exchanging completely within 15 minutes to 2 hours, ensuring a balanced daily production and absorption of roughly 500 mL to maintain a steady-state volume of 50–100 mL in the peritoneal cavity.^[10] In peritoneal dialysis, these inherent mechanisms are leveraged by infusing hyperosmotic dialysate to amplify ultrafiltration via osmotic gradients, facilitating solute removal while relying on lymphatic and tissue absorption for fluid clearance.^[1]

Functions

Peritoneal fluid serves primarily as a lubricant within the peritoneal cavity, forming a thin serous layer that minimizes friction between abdominal organs and the peritoneal membranes during physiological movements such as respiration, peristalsis, and postural changes, thereby preventing tissue damage and the formation of adhesions.^[2] This lubricating function is facilitated by the fluid's composition, including phospholipids and glycosaminoglycans secreted by mesothelial cells, which create a low-friction interface essential for organ mobility.^[11] In addition to lubrication, peritoneal fluid plays a key role in the transport of nutrients, gases, and waste products, enabling the diffusion of oxygen and essential metabolites from blood vessels to adjacent organs while facilitating the removal of metabolic byproducts through convective and diffusive mechanisms across the peritoneal membrane.^[11] This transport occurs via ultrafiltration from plasma and selective permeability of the mesothelium and capillary endothelium, supporting cellular metabolism in the absence of direct vascular supply to some peritoneal structures.^[3] The fluid also contributes to immune surveillance by harboring resident immune cells, including macrophages and lymphocytes, which perform phagocytosis of pathogens, cellular debris, and foreign particles, while humoral components such as complement proteins (e.g., C3, C4) and immunoglobulins (e.g., IgG) enhance antimicrobial defenses.^[3] These elements allow the peritoneal cavity to act as a dynamic reservoir for immune cells, enabling rapid mobilization during local threats and maintaining homeostasis through continuous monitoring and clearance activities.^[11] As a barrier, peritoneal fluid provides selective permeability that restricts the uncontrolled spread of infections or malignant cells while permitting necessary solute exchange, with microvilli on mesothelial surfaces trapping bacteria and particulates to localize potential threats.^[3] This function is bolstered by the fluid's ability to filter and drain waste, protecting underlying organs from invasive particles through a combination of physical separation and immune-mediated responses.^[2] Furthermore, the fluid supports fibrinolysis through the presence of plasminogen activators, such as tissue plasminogen activator (tPA) produced by mesothelial cells, which degrade fibrin clots to inhibit adhesion formation and promote the resolution of minor inflammatory events.^[11] This fibrinolytic activity is balanced by inhibitors like plasminogen activator inhibitor-1 (PAI-1), ensuring controlled clot management without excessive bleeding.^[11]

Composition

Normal Components

Peritoneal fluid in healthy individuals is an ultrafiltrate of plasma, formed through filtration across the peritoneal membrane, which imparts a transudate character with low solute concentrations relative to plasma.^[14] Its electrolyte profile closely mirrors that of plasma, featuring sodium at approximately 140 mEq/L, potassium at 4 mEq/L, and chloride at 100 mEq/L.^[14] Protein content remains low, with total protein ranging from 1 to 2 g/dL and albumin below 2.5 g/dL, predominantly comprising albumin and globulins.^[15] Cellular elements consist of shed mesothelial cells from the peritoneal lining, macrophages (typically 50-200/mm³, comprising the majority), lymphocytes, and rare neutrophils, yielding a total nucleated cell count under 300/mm³.^[16]^[17] Additional components include glucose levels comparable to serum, low lactate dehydrogenase (LDH) activity (fluid-to-serum ratio <0.6), normal amylase (equal to or below serum levels), pH in the range of 7.4-7.6, and specific gravity between 1.004 and 1.010.^[18]^[15]^[19] Healthy peritoneal fluid lacks bacteria and exhibits minimal red blood cells (<1000/mm³).^[20]

Volume and Characteristics

In healthy adults, the normal volume of peritoneal fluid ranges from 5 to 20 mL (up to approximately 25 mL in females during the ovulatory cycle), serving as a thin lubricating layer within the peritoneal cavity.^[21]^[22]^[23] The fluid typically appears clear and straw-colored, reflecting its serous nature derived from mesothelial cell secretion.^[15] Its viscosity is low to facilitate smooth organ movement, primarily influenced by mucopolysaccharides such as hyaluronic acid produced by peritoneal mesothelial cells.^[24] The specific gravity of normal peritoneal fluid falls between 1.003 and 1.009, closely resembling that of plasma ultrafiltrate.^[25] Measurement of peritoneal fluid volume in healthy individuals is not routine but can be estimated in research settings using imaging techniques like ultrasound or CT, which provide accurate assessments even for small volumes under 10 mL.^[26] These methods confirm the fluid's steady-state presence without pathological accumulation.^[27]

Pathophysiology

Ascites

Ascites refers to the pathologic accumulation of fluid within the peritoneal cavity, often leading to abdominal distension.^[4] Ascites is classified using the serum-ascites albumin gradient (SAAG), which helps distinguish portal hypertension-related (high SAAG ≥1.1 g/dL, often transudative) from non-portal hypertension-related (low SAAG <1.1 g/dL, often exudative) causes.^[28] Historically, total protein levels were used (<25 g/L for transudates, ≥25 g/L for exudates), but SAAG is more accurate.^[29] Transudative ascites commonly results from systemic factors altering fluid dynamics, whereas exudative ascites arises from local peritoneal processes.^[29] Epidemiologically, ascites is a frequent complication in patients with liver disease, particularly cirrhosis, where it develops in approximately 50% of cases within 5 to 10 years of diagnosis.^[4] The annual incidence in compensated cirrhosis is about 5% to 10%, reflecting its role as a key decompensating event.^[30] In developed countries, cirrhosis accounts for around 80% of ascites cases, underscoring portal hypertension as the predominant etiology.^[31] The primary causes of ascites include portal hypertension, most often due to cirrhosis, but also from other conditions such as malignancy, heart failure, and nephrotic syndrome.^[31] Hypoalbuminemia, frequently seen in liver disease or nephrotic syndrome, reduces plasma oncotic pressure, contributing to fluid leakage into the peritoneal space.^[32] Malignancy-related ascites, often exudative, stems from peritoneal carcinomatosis or lymphatic obstruction.^[4] Pathophysiologically, ascites arises from an imbalance in Starling forces across peritoneal capillaries, where increased hydrostatic pressure from portal hypertension drives fluid out, while reduced oncotic pressure from hypoalbuminemia impairs reabsorption.^[33] This is compounded by systemic effects, including splanchnic vasodilation that activates the renin-angiotensin-aldosterone system, leading to renal sodium and water retention and further fluid overflow into the peritoneal cavity.^[23] The International Ascites Club provides a standardized grading system: Grade 1 denotes mild ascites detectable only by ultrasound; Grade 2 indicates moderate ascites with symmetrical abdominal distension; and Grade 3 represents tense ascites causing marked distension.^[34] This classification guides clinical management by assessing severity and symptom burden.^[35] Complications of ascites include spontaneous bacterial peritonitis (SBP), an infection of ascitic fluid occurring in up to 30% of hospitalized cirrhotic patients, which carries high mortality if untreated.^[36] Increased intra-abdominal pressure can lead to umbilical herniation, potentially resulting in incarceration, strangulation, or rupture (Flood syndrome).^[37] Severe ascites may also cause respiratory compromise by elevating the diaphragm and restricting lung expansion.^[38]

Peritonitis

Peritonitis is the inflammation of the peritoneum, the serous membrane lining the abdominal cavity and covering the abdominal organs, typically resulting from bacterial or fungal infection, chemical irritants, or ischemia, which leads to the production of turbid, exudative peritoneal fluid.^[39]^[40] This inflammatory response disrupts the normal homeostasis of the peritoneal cavity, causing fluid accumulation rich in proteins and inflammatory cells.^[41] Peritonitis is classified into several types based on etiology and source. Primary peritonitis, also known as spontaneous bacterial peritonitis (SBP), occurs without an identifiable intra-abdominal source of infection and is common in patients with ascites, often due to bacterial translocation from the gut; Escherichia coli is a frequent causative organism in these cases.^[42]^[43] Secondary peritonitis arises from perforation of a hollow viscus, such as the appendix or intestines, or from surgical complications, allowing direct contamination of the peritoneal space.^[39] Tertiary peritonitis refers to persistent or recurrent infection following inadequate treatment of primary or secondary forms, often involving resistant organisms.^[42] The pathophysiology involves bacterial translocation across the intestinal barrier into the peritoneal fluid, particularly in compromised hosts, triggering an intense inflammatory cascade.^[42] Endotoxins from gram-negative bacteria like E. coli stimulate cytokine release from macrophages and mesothelial cells, leading to vasodilation, increased vascular permeability, and exudation of protein-rich fluid with elevated white blood cell (WBC) counts, predominantly polymorphonuclear leukocytes (PMNs).^[41] This results in fibrin deposition and potential loculation of infected fluid, exacerbating the inflammatory response.^[41] Symptoms of peritonitis typically include acute abdominal pain that worsens with movement, fever, rebound tenderness on palpation, and abdominal distension; in cases involving peritoneal fluid analysis, the fluid appears cloudy due to high cellularity.^[39]^[40] Complications can be severe, including intra-abdominal abscess formation, systemic sepsis with multi-organ dysfunction, and chronic adhesions or fibrosis that may lead to bowel obstruction.^[42]^[40] In patients with underlying liver disease, mortality rates can exceed 40% due to sepsis progression.^[42] Risk factors for peritonitis include liver cirrhosis with ascites, peritoneal dialysis, abdominal trauma, and conditions predisposing to bacterial overgrowth or immune deficiency.^[39]^[42] Diagnosis is supported by paracentesis revealing peritoneal fluid with PMN count greater than 250 cells/mm³, often with positive cultures confirming infection.^[42]

Analysis

Paracentesis Procedure

Paracentesis is a minimally invasive procedure involving the insertion of a needle or catheter into the peritoneal cavity to aspirate fluid, performed either diagnostically to analyze ascites or therapeutically to alleviate symptoms from fluid accumulation.^[44] It is commonly used in patients with liver cirrhosis, where ascites is prevalent, and requires ultrasound guidance to enhance safety and accuracy.^[45]

Indications

Diagnostic paracentesis is indicated for new-onset ascites to determine its etiology, suspected spontaneous bacterial peritonitis in patients with known ascites, or to evaluate for infection in hospitalized individuals with ascites.^[44] Therapeutic paracentesis is recommended for tense ascites causing discomfort, respiratory compromise, or abdominal distension, particularly when removing more than 5 liters of fluid to relieve symptoms.^[46]

Contraindications

Absolute contraindications include disseminated intravascular coagulation and an acute abdomen necessitating surgical intervention.^[44] Relative contraindications encompass pregnancy, significant organomegaly, ileus, severe coagulopathy (such as platelet count below 20,000/μL or INR greater than 2.0), and the presence of surgical scars in the abdominal wall, which may increase procedural risks.^[44] Bowel distension is also a precaution, requiring correction prior to the procedure.

Technique and Steps

The procedure is typically performed under ultrasound guidance to identify optimal fluid pockets and avoid vascular or bowel structures, using a percutaneous approach in the left or right lower quadrant, lateral to the rectus sheath and 2-4 cm superomedial to the anterior superior iliac spine.^[44] The patient is positioned semi-recumbent or supine with a wedge for comfort, and the area is prepared sterilely with local anesthesia using 1% lidocaine.^[47] A small skin nick is made, followed by insertion of an 18- to 20-gauge catheter via the Z-track method to minimize leakage; for diagnostic purposes, 25-30 mL of fluid is aspirated, while therapeutic removal can safely extract up to 4-6 liters without mandatory albumin replacement, though larger volumes (>5 liters) require post-procedure albumin infusion (6-8 g per liter removed) to prevent circulatory dysfunction.^[44] Fluid is collected in sterile containers for analysis, and the catheter is removed with pressure applied to the site; patients are monitored afterward for signs of hypotension or bleeding.^[47]

Complications

Paracentesis carries a low overall complication rate of approximately 1%, with common issues including persistent ascitic fluid leakage at the insertion site, abdominal wall hematoma, wound infection (around 0.5%), and bowel perforation (less than 1%).^[46] Post-procedure hypotension may occur after large-volume removal exceeding 5 liters, potentially leading to hepatorenal syndrome if not mitigated by albumin administration.^[44] Ultrasound guidance significantly reduces these risks by improving procedural success.^[45]

History

Abdominal paracentesis has ancient origins. Ascites was first described in Egyptian texts like the Papyrus Ebers around 1550 BCE, and the procedure was first described by Hippocrates (460-370 BCE), who cautioned against excessive drainage.^[48] Roman physician Aulus Celsus documented the technique around 20 BCE using a trochar and cannula.^[49] Modern advancements, including routine ultrasound guidance, emerged in the 1970s, enhancing safety for interventional fluid aspirations, with randomized trials in the 1980s and 1990s establishing large-volume paracentesis with albumin as a standard for managing refractory ascites.^[50]^[51]

Laboratory Evaluation

Laboratory evaluation of peritoneal fluid begins with a gross examination of the sample, which provides initial clues to the underlying pathology. Normal peritoneal fluid is typically clear and straw-colored, while cloudy or turbid fluid often indicates infection or inflammation, such as in spontaneous bacterial peritonitis (SBP) or peritonitis. Milky appearance suggests chylous ascites due to lymphatic leakage, and bloody fluid may point to trauma, malignancy, or tuberculosis.^[52] A complete blood cell count with differential is essential, focusing on the white blood cell (WBC) count and neutrophil percentage. An absolute polymorphonuclear (PMN) leukocyte count exceeding 250 cells/mm³ is a key diagnostic threshold for SBP, with a predominance of neutrophils (>50%) supporting bacterial infection. Lymphocyte predominance may suggest tuberculous peritonitis or malignancy. Total WBC counts above 500 cells/mm³ warrant further investigation for infectious or neoplastic processes.^[52]^[53] Chemical analysis includes measurement of total protein, lactate dehydrogenase (LDH), glucose, and amylase levels. Total protein concentration helps classify the fluid, with levels below 2.5 g/dL typically indicating a transudate (e.g., from portal hypertension) and above 2.5 g/dL suggesting an exudate (e.g., from infection or malignancy). LDH levels greater than the upper limit of normal for serum support an exudative process. Glucose concentrations below 50 mg/dL are associated with infections like SBP or tuberculosis, where bacterial consumption depletes the sugar. Elevated amylase (>100 times serum levels) indicates pancreatic or gastrointestinal leakage, as seen in pancreatitis or perforation.^[54]^[52] The serum-ascites albumin gradient (SAAG) is calculated as serum albumin minus ascites albumin and is a cornerstone for differentiating causes of ascites. A SAAG greater than 1.1 g/dL (or 11 g/L) indicates portal hypertension-related ascites, such as in cirrhosis (sensitivity 97%, specificity 90%), while a gradient below 1.1 g/dL points to non-portal hypertensive causes like malignancy or infection. This metric outperforms traditional transudate-exudate classification based solely on protein.^[55]^[54] Microbiological studies are critical for detecting infection. Gram staining identifies bacteria in about 10-30% of SBP cases, while aerobic and anaerobic cultures confirm pathogens, though up to 60% may be culture-negative in SBP. Acid-fast bacilli (AFB) staining and culture are performed for suspected tuberculous peritonitis, albeit with low sensitivity (0-6%); adjunctive PCR improves detection to 94% sensitivity.^[52] Cytological examination is vital for diagnosing malignancy, particularly in ovarian cancer, where atypical or malignant cells are detected in 50-70% of cases with peritoneal involvement. Sensitivity varies by tumor type and stage, but cytology remains the gold standard for confirming neoplastic ascites.^[56] Additional tests include triglyceride and bilirubin levels. Triglyceride concentrations above 200 mg/dL confirm chylous ascites from lymphatic disruption. Elevated bilirubin (> serum levels) indicates bile leak from gallbladder or biliary tract injury.^[57]^[52] Interpretation integrates these findings to classify ascites. Adapted Light's criteria for exudates include ascitic fluid protein >2.5 g/dL or LDH exceeding the serum upper limit of normal, though SAAG is preferred for etiological diagnosis. High SAAG with low protein suggests transudative ascites from portal hypertension, while low SAAG with high protein or LDH indicates exudative causes like malignancy or infection. These evaluations guide targeted therapy and prognosis.^[58]^[54]

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Oct 24, 2025 · ... 1,500 mL of ascites needs to be present. The ... The paracentesis Z technique is performed to minimize the risk of a peritoneal fluid leak.<|control11|><|separator|>
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10. Paracentesis | Hospital Handbook
General Considerations. Indications: Diagnostic: to determine etiology of ascites or rule-out SBP in known ascites. Therapeutic: to relieve symptoms of ...
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Historical Aspects of Ascites and the Hepatorenal Syndrome - PMC
Oct 29, 2021 · The Early Days of Paracentesis ... Ascites or abdominal dropsy has been known since antiquity, according to descriptions in The Papyrus Ebers from ...
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History - Liver & Ascites Exam - Physical Diagnosis Skills
Fluid accumulation in the abdomen was recognized in ancient times. Celsus is credited with first describing in ~20 BC the technique of paracentesis.Missing: procedure | Show results with:procedure
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The History of Interventional Ultrasound - McGahan - 2004
Jun 1, 2004 · Ultrasound has been used to guide interventional procedures for more than 30 years. Initial applications included biopsy techniques and simple ...History · Biopsy Techniques · Fluid Aspiration/Drainage · Sonographically Guided...
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https://doi.org/10.1016/0016-5085(87)91007-9
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Ascitic Fluid Analysis in the Differential Diagnosis of Ascites - NIH
29 SAAG is generally low (<1.1 g/dL) in ascites ... Serum protein concentration and portal pressure determine the ascitic fluid protein concentration in patients ...
[53]
etiologies, ascitic fluid analysis, diagnostic algorithm - PubMed
Dec 20, 2023 · Routine ascitic fluid analysis should include the serum ascites albumin gradient (SAAG), total protein concentration, cell count and differential.
[54]
Biochemical Analysis of Pleural Fluid and Ascites - PMC - NIH
In peritoneal fluid, albumin is the most useful test, for the ... Physiology and pathophysiology of pleural fluid turnover. Eur Respir J. 1997 ...
[55]
The Serum-Ascites Albumin Gradient Is Superior to the Exudate ...
Objective: To compare the serum-ascites albumin gradient to the exudate-transudate concept in the classification of ascites.Missing: original paper
[56]
Ascites in Ovarian Carcinoma – Reliability and Limitations of ... - NIH
The sensitivity of peritoneal cytology stated in other studies ranges from only 50 to 60% (in our research it was 68.92%), up to 97% depending on the study, ...
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Chylous Ascites: A Review of Pathogenesis, Diagnosis and Treatment
Dec 4, 2017 · The lymphatic system of the abdomen is comprised of cisterna chyli and its main tributaries, the common intestinal trunk and the lumbar trunks.
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Ascites Fluid - an overview | ScienceDirect Topics
•. Serum-ascites albumin gradient (SAAG): Difference of < 11 g/L suggests exudative ascites. ○. Protein: < 2.5 g/dl = transudate; > 2.5 g/dl = exudate.