SciELO - Scientific Electronic Library Online

 
vol.110 issue12Graft survival after liver transplantation: an approach to a new Spanish risk indexConsensus document on exclusion diets in irritable bowel syndrome (IBS) author indexsubject indexarticles search
Home Pagealphabetic serial listing  

My SciELO

Services on Demand

Journal

Article

Indicators

Related links

  • On index processCited by Google
  • Have no similar articlesSimilars in SciELO
  • On index processSimilars in Google

Share


Revista Española de Enfermedades Digestivas

Print version ISSN 1130-0108

Rev. esp. enferm. dig. vol.110 n.12 Madrid Dec. 2018

http://dx.doi.org/10.17235/reed.2018.5705/2018 

REVIEW

High-resolution and high-definition anorectal manometry: rediscovering anorectal function

Constanza Ciriza-de-los-Ríos1  , Miguel Mínguez2  , José-María Remes-Troche3  , Glòria Lacima4 

1Servicio de Aparato Digestivo. Unidad de Motilidad Digestiva. Hospital Universitario 12 de Octubre. Madrid, Spain

2Servicio de Aparato Digestivo. Unidad de Motilidad Digestiva. Hospital Clínico Universitario. Universidad de Valencia. Valencia, Spain

3Laboratorio de Fisiología Digestiva y Motilidad Gastrointestinal. Instituto de Investigaciones Médico-Biológicas. Universidad Veracruzana. Veracruz, México

4Departamento de Cirugía Gastrointestinal. Unidad de Motilidad Digestiva. Instituto Clínic de Enfermedades Digestivas y Metabólicas. Hospital Clínic. IDIBAPS. CIBERehd. Universidad de Barcelona. Barcelona, Spain

INTRODUCTION

Anorectal disorders affect 15-20% of the population, and most result from neuromuscular changes in the pelvic floor and adjacent structures 1,2. Neurophysiological testing to assess anorectal function provides highly significant information on the pathophysiological mechanisms involved in the genesis of fecal incontinence, pelvic floor dyssynergia, rectal hypo- or hypersensitivity, and pelvic neuropathy 3.

Anorectal manometry (ARM) is a technique that, by simultaneously recording intraluminal pressure changes at multiple levels, allows to assess anorectal motor activity both at rest and mimicking multiple physiological situations (rectoanal inhibitory reflex, retention effort, defecation maneuver, Valsalva reflex).

While barostat represent the gold standard in the evaluation of rectal sensitivity, ARM may also assess it provided the device is fitted with a distensible rectal balloon. This technique, together with balloon expulsion testing, is used in standard clinical practice for the diagnosis of defecatory disorders in patients with constipation refractory to standard therapy with hygienic-dietary measures and laxatives 4, in the assessment of patients with fecal incontinence 5, to administer biofeedback therapy to patients with constipation and/or fecal incontinence, in the assessment of anorectal pain syndromes (proctalgia), and even for the preoperative and postoperative evaluation of ileorectal anastomoses 6.

High-resolution anorectal manometry (HR-ARM) and high-definition anorectal manometry (HD-ARM), available since 2007, are increasingly used in clinical practice. In comparison to the conventional technique, HR-ARM and HD-ARM catheters provide a greater number of recording points thanks to their multiple, closely packed circumferential sensors. This allows time-space visualization (topographic or 2-3-plane mode) as spatially continuous measurements are obtained by interpolation between near sensors, as well as a clearer assessment of anal/rectal pressure changes, without interference from catheter shifting with pelvic floor movements 7 (Fig. 1). The technique is more intuitive and reproducible, and has better inter-observer agreement when compared to the conventional procedure 8,9. It is also easier to perform, as the whole study may be carried out without catheter mobilization, and more accurate regarding the relationship between balloon distension and motor response. It reduces errors from pelvic floor movements (artifact minimization), and allows ongoing recording on balloon inflation for cases with short or low-pressure anal canal, which may be challenging with conventional manometry. However, the benefit of HR-ARM over standard manometry in clinical practice is less obvious in the anorectal area as compared to the esophagus 10. Furthermore, equipments are expensive, and catheters more fragile 7.

Fig. 1 Resting anal canal pressure and maximum voluntary contraction pressure using conventional, high-resolution, and high-definition manometry. A and D. Conventional tracings for anal canal resting pressure and maximum voluntary contraction pressure. B and E. A space-time topography of high-resolution manometry, where anal canal length and pressure at rest (B) and during contraction (E) are better visualized in color. High-definition manometry provides a 3-plane (3D) reconstruction of the anal canal, and images C and F show the morphology of the anal sphincter at rest and during maximum voluntary contraction (original image). 

The technique has few contraindications, particularly serious medical or psychological conditions that may preclude patient cooperation during the procedure, presence of anal or rectal disorders that may impede catheter insertion (stricture, anorectal obstruction), and infectious diarrhea 10.

OBJECTIVE

To review the equipments and technical characteristics of novel anorectal manometry modalities, emphasizing the values observed in the healthy population (reference) and discussing the newly available measurement parameters.

METHODOLOGY

A narrative literature review was performed using the MEDLINE database. Search terms included: anorectal manometry, anorectal manometry AND sensitivity OR specificity, high-resolution anorectal manometry, anorectal manometry AND solid-state OR water-perfused catheters, anorectal manometry AND 3D high-definition OR high-resolution. Only texts in English or Spanish were analyzed.

EQUIPMENTS AND CATHETERS

As with conventional manometry, HR-ARM may use either continuous perfusion systems with external transducers and open-end catheters with side holes, or systems incorporating pressure microtransducers in the exploring probe, which directly record intraluminal pressure changes 10.

Perfusion systems have the drawback of requiring ongoing catheter perfusion with bidistilled water, which leads to continuous water outflow into the anal canal and rectal ampulla. Furthermore, increasing the number of recording points with perfusion systems only may be done longitudinally, never covering the entire circumference in the axial plane. These limitations are minor when catheters with solid-state microtransducers are used 11. Currently, the most commonly employed HR-ARM devices are those manufactured by Medtronic(r) (previously Sierra(r) and Given Imaging(r)), Medical Measurements(r), and Diversatek(r) (previously Sandhill(r)), whereas HD-ARM devices are only available from Medtronic(r).

Catheters vary in outer diameter and number of sensors, usually oscillating between 8 and 12, capturing pressure data in the rectum, anus, and atmosphere.

Medtronic(r) High-Resolution Manometry System

It includes an adult catheter with an outer diameter of 4.2 mm, and has 12 circumferential sensors - of these, at least 8 are to be placed in the anal canal - 2 usually remain outside (external reference) - and 2 in the rectum within a 3.3 cm-long balloon with a capacity of 400 mL. These catheters use a novel solid-state technology for pressure transduction (tactile array sensors) to capture data at 35 Hz, and provide one mean pressure value for the whole circumference at 6-mm intervals all along the anal canal, thus obviating the need for station withdrawal. These sensors are very sensitive to temperature changes, which results in pressure measurements; it is for this reason that thermal compensation is required on test completion to correct this deviation. On extraction, the catheter must be kept at room temperature for a few seconds, without bringing pressure to bear on its sensors. As regards durability, a mean service life of 200 procedures is guaranteed 7.

The system's software is similar to that of high-resolution esophageal manometry, and includes a data acquisition module (ManoScan AR; Medtronic(r)) and a data analysis module (Manoview AR; Medtronic(r)). It also includes the "eSleeve" option, a data processing tool that simplifies the data sequence of selected sensors to a single pressure value for all pressures recorded in the anal canal. At rest, during voluntary contraction, and during rectal distension the "sleeve" identifies the highest pressure recorded by the sensors at each point in the anal canal. This accounts for the fact that pressures obtained by HR-ARM are higher than those recorded by standard manometry. During the defecation maneuver the "sleeve" identifies the difference in more positive or less negative pressure between the rectum and the anus over a period of 20 seconds 12.

Medtronic(r) High-Definition System

Its catheter has a length of 6.4 cm with an outer diameter of 10.75 mm, and includes 256 sensors, which provide true recordings with individualized circumferential measurements. The space between sensors is 4 mm axially and 2 mm radially. The rectal balloon is 3.3 cm long and has a maximum capacity of 400 mL.

The software allows volumetric representations of the anal canal in addition to 2D visualization and standard line tracings. The 3D pressure map allows rotation of the pressure cylinder to assess the entire morphology and more easily identify asymmetries. The program also permits to open the cylinder longitudinally to examine selected pressure areas; thus, any point in the anorectal pressure morphology may be clearly assessed 13.

Medical Measurement(r) High-Resolution System

The catheter has an outer diameter of 4 mm and includes 8 directional sensors. Six of them are equidistant from each other by 5 cm. The most proximal sensor is located within the rectal balloon (3.3 cm in length, maximum capacity of 400 mL) and 2.5 cm away from the other sensors. The most distal sensor serves as external reference. The data acquisition and analysis software is the es Solar GI HRM package (v 9.1; MMS, Enschede, the Netherlands) 13. Perfusion catheters with 8 sensors and holes 0.5 or 1 cm apart are also available.

Diversatek(r) (previously Sandhill(r)) High-Resolution System

It includes a catheter 4 mm in outer diameter and 8 directional, solid-state sensors. The most proximal sensor is located inside the rectal balloon; distal to this a sensor is placed in the rectum, 5 sensors 10 mm apart from each other are placed in the anal canal, and an external reference sensor is placed outside the anal margin. The pressures recorded in the anal canal are averaged to obtain a mean value. The balloon is 3.3 cm long, with a maximum capacity of 400 mL. Data are analyzed with the Bioview Analysis software (InSIGHT G3 HRiM or InSIGHT Ultima system; Sandhill Scientific) 13.

The superiority of solid-state catheters over perfusion catheters for the assessment of abrupt pressures changes in the anal canal during maneuvers such as voluntary contraction (squeeze) or cough has been recently confirmed 14.

Another aspect to consider is whether HR-ARM and HD-ARM are comparable, and the longitudinal analysis seems to show good agreement between both techniques in the assessment of resting pressure and voluntary contraction 15.

PROCEDURE

While not physiological for bowel voiding, the procedure is usually performed with the patient in the left lateral decubitus position for technical convenience, and standardized normal values are available for this setting. The procedure starts after a period of patient adaptation to the probe for 3-5 min 10,16. In every exploration the following is assessed:

  • Anorectal resting pressure: usually recorded over 20 seconds, except when ultra-slow waves (1-1.5 cycles/min) are detected, where the period is extended to at least one minute 10,13,17. These waves may be previously identified during the stabilization period.

  • Maximum voluntary contraction pressure: three maneuvers, each lasting 20-30 seconds followed by a resting lapse of at least 30 seconds 10,17. It was recently suggested that, in addition to sustained contraction, rapid voluntary contractions may also be assessed, but the clinical usefulness thereof remains uncertain 18.

  • Cough maneuver (cough reflex, three iterations) to assess extrinsic nerve supply integrity. It is performed on a deflated balloon and after 50-mL inflation.

  • Defecatory maneuver (three attempts): performed on a deflated balloon and after 50-mL inflation with air, the interval between maneuvers being 30 seconds 10,13.

  • Anorectal inhibitory reflex and rectal sensitivity: simultaneously recorded, internal anal sphincter relaxation is gradually assessed during rectal balloon distension in increments of 10-20 mL; distension perception threshold, defecatory urgency, and maximum tolerable volumes are assessed. The examination may be completed by exploring other reflexes and performing a balloon expulsion test 17.

DATA ANALYSIS AND INTERPRETATION

Graphic visualization modes (topography, line tracing) may be alternated to facilitate the analysis of ARM recordings. Parameters developed for conventional manometry and later adapted to the newer systems are usually assessed.

TRADITIONAL PARAMETERS

Anal canal resting pressure

Similarly to conventional manometry, normal resting pressure values depend on both patient-related factors (e.g., age, gender, parity, and more uncertainly body mass index and race) and equipment-related factors 17,19,20,21. Values obtained with the Sandhill(r) system are lower than those recorded by other devices 22. As with conventional manometry, higher pressures are usually recorded in patients with anal fissure or pain (because of striated or smooth muscle spasm) 23, and lower pressures are seen in patients with impaired internal anal sphincter and fecal incontinence 24. However, variability is high among healthy individuals 20, probably because sample size remains small in studies with healthy subjects. According to catheter type, resting pressure may be considered as related to either a rectal or external reference value. Importantly, measured values must be assessed using atmospheric pressure as their reference, as this generally assesses the structures making up the anorectal unit, and biases, variations, and artifacts are less common. While it is an expert recommendation, no evidence is found in the literature assessing the actual difference between absolute and atmospheric values in anorectal structures within a clinical context.

High-resolution perfusion devices always use an intrarectal reference.

High pressure zone length

The length of the mean pressure profile within the resting pressure frame, defined as: [rectal pressure + (anal resting pressure - rectal pressure) x 0.25] 17,19. Short anal canals have been seen to be associated with fecal incontinence 18.

Maximum voluntary contraction pressure

As with resting pressure, this parameter is dependent on factors such as age, gender, and measuring equipment 17,19,20,22. Absolute maximum voluntary contraction pressure and pressure increases from resting pressure should both be assessed 13. As with resting pressure, some systems allow using intrarectal or atmospheric pressure as reference.

A low pressure measurement usually reflects a hypotonic external anal sphincter (EAS) because of muscle or nerve injury 24.

Voluntary contraction duration

The most widely accepted criterion to assess this parameter is considering the period (in seconds) the patient is able to sustain voluntary contraction pressure until its fall by more than 50%. A short voluntary contraction suggests fatigue or skeletal muscle injury.

Cough maneuver (cough reflex)

The abrupt increase in abdominal pressure associated with cough induces the contraction of the EAS. This maneuver allows to indirectly assess the sacral reflex arc, which is a spinal reflex. While no significant differences have been previously reported between HR-ARM and the standard technique 16, it has been recently shown that solid-state catheters seem superior in assessing abrupt pressure changes in the anal canal 14. A maximum anal canal pressure higher than the maximum rectal pressure is deemed to be normal.

Defecatory maneuver

Normal defecation involves a sufficient increase in rectal pressure that is coordinated with anal sphincter and pelvic floor muscular relaxation. During the defecatory maneuver the eSleeve tool identifies the most positive (or less negative) difference in pressure between the rectum and anus over 20 seconds 17,19. The parameters assessed in a normal defecatory maneuver include intrarectal pressure (mmHg), residual anal pressure (mmHg), anorectal pressure (mmHg) or rectoanal gradient, percent anal relaxation, and defecatory index. Importantly, these parameters were developed for conventional systems, and their adaption to HR-ARM and HD-ARM has been challenging.

Rectoanal gradient is defined as rectal pressure minus residual anal pressure, hence a positive gradient indicates a normal defecatory maneuver using the standard approach. However, when using HR-ARM or HD-ARM this gradient is negative in a large proportion of healthy subjects17,19,25, particularly when the maneuver is performed on a deflated balloon. Therefore, it does not seem to be a good index to discriminate between healthy individuals and patients with dyssynergic defecation. Furthermore, rectoanal gradient results are dependent on the position adopted during the defecation maneuver (lateral decubitus or sitting), and balloon inflation status 26,27.

Percent anal relaxation is defined as anal relaxation pressure divided by anal resting pressure and multiplied by 100. Values of at least 20% are considered normal.

Defecatory index results from dividing maximum rectal pressure by residual anal pressure during the defecation maneuver. A value higher than 1.5 is considered normal.

Based on these parameters defecatory dyssynergia has been categorized in at least 4 subtypes 28:

  • Type I: adequate propulsive forces (intrarectal pressure > 45 mmHg) but with increase in anal pressure.

  • Type II: inability to generate adequate expulsive forces (intrarectal pressure < 45 mmHg) together with paradoxical increase in residual intra-anal pressure.

  • Type III: adequate propulsive forces with absent or inadequate baseline pressure relaxation (< 20%).

  • Type IV: inability to generate adequate expulsive forces, that is, without increase in intrarectal pressure, and absent or inadequate baseline pressure relaxation (< 20%).

Types I and III are classically described as pelvic floor dyssynergia, whereas types II and IV involve inadequate defecatory propulsion. Recently, identifying these subtypes has been reported to be feasible and easier using HR-ARM 29,30 (Fig. 2).

The fact that conventional manometry provided few recording points, and many of the defecatory maneuvers that were deemed normal might be the result of a shifting catheter, must be borne in mind. In the study by Sauter et al 12 false relaxations were seen in up to 55% of cases because of catheter shifts, which is considerably reduced when using HR-ARM.

Fig. 2 Dyssynergic defecation classification according to manometric pattern using high-resolution manometry. Conventional anorectal manometry tracings are seen on the left side, and those of high-resolution manometry on the right side. The red line in conventional manometry represents intrarectal pressure, and the blue line represents anal pressure during defecatory maneuver. As may be seen, types I and III are characterized by paradoxical contraction or absent anal sphincter relaxation, whereas types II and IV are characterized by weak or absent rectal propulsion. High-resolution manometry tracings show two colored bands, a thin one above (rectal) and a thick one below (anal), where brighter colors represent higher pressures and paler colors represent lower pressures. Reproduced with permission from: Remes-Troche JM, Coss-Adame E, Lopéz-Colombo A, et al. The Mexican consensus on chronic constipation. Rev Gastroenterol Mex 2018;pii S0375-0906(18)30047-8. DOI: 10.1016/j.rgmx.2017.12.005 

Anorectal inhibitory reflex

This reflex is deemed to be present when internal anal sphincter relaxation is > 25% as compared to baseline pressure in the anal canal 17. Amplitude and duration depend on distension volume in the rectum. This reflex is absent in Hirschsprung's disease.

Rectal sensitivity

It is assessed using balloon rectal distension, considering the perception of said distension (first sensation, urgency, and maximum tolerated volume). During each distension, the percentage of anal relaxation is calculated as [(1-residual anal pressure /resting anal pressure) x 100] 17,19. Increased rectal sensitivity is associated with urgency incontinence, proctitis, or irritable bowel syndrome when using conventional manometry. In contrast, decreased sensitivity is associated with passive incontinence and chronic constipation.

NORMAL VALUES

Normal values have been reported for the aforementioned systems and catheters, and significant differences according to type, in addition to those dependent on factors such as age, gender, parity, BMI 31, etc.

Normal values reported for anal canal pressures, rectal sensitivity, and defecatory maneuvers with HR-ARM in both men and women are listed in Table 1. Normal values for HD.-ARM are listed in Table 2.

No normal values are available for the Spanish population, hence a multicenter study might be considered to provide reference values at a national level, both for solid-state and perfusion high-resolution systems.

Table 1 Normal values reported for anal canal, defecatory maneuver, and rectal sensitivity pressures in healthy women and men using 9-23-sensor HR-ARM catheters 

( ) 95% CI; *p < 0.05 vs. < 50 years; †p < 0.05 versus men; ‡p < 0.05 versus nulliparae; ND: no data.

The Grupo Español de Motilidad Digestiva (GEMD) is now launching a multicenter study with the Medtronic(r) system to obtain reference values on a national scale. The challenge we are taking on is to ultimately establish normal values in a group of healthy, asymptomatic volunteers - using an adequate sample size estimation (larger than heretofore reported) - both for solid-state and perfusion high-resolution systems, considering subject-related factors, and relying on a consensus methodology to promote technical standardization, so that results may be transferred between institutions on an international scale as is already the case with high-resolution esophageal manometry, which would facilitate reliability in multicenter studies, research advancement, and then higher diagnostic efficiency.

NEW HR-ARM AND HD-ARM PARAMETERS AND INTERPRETATION

A criticism of conventional manometry was lack of standardization. HR-ARM and HD-ARM allow a more standardized, reproducible use of the technique 32.

Indisputably, these technologies allow to better research and understand the functional anatomy of the sphincter complex, providing a detailed distribution of pressures in the anal canal, and both their axial and circumferential asymmetries 33,34. While appropriate parameters for these systems are now under development and evaluation by various research teams, many cannot be used in clinical practice yet; however, they do provide highly relevant information allowing a redefinition of anorectal anatomy and physiology.

Temporo-spatial topographic analysis provides a qualitative description, including visualization of two pressure zones in the anal canal during voluntary contraction, representing EAS (distal) and puborectalis muscle (proximal) contractions, which allows an assessment of paradoxical puborectalis contraction 20,35. It also permits to observe different voluntary contraction morphologies in healthy individuals, and spontaneous anal canal activity as in transient relaxations (20) (Fig. 3A and Fig. 3B). The latter have a mean duration of 23 seconds in healthy individuals, are more common in the postprandial period, and produce symptoms in up to 76% of cases (urge to break wind). Changes in transient relaxation characteristics or perception are likely relevant in fecal incontinence 36. In patients with proctalgia fugax HR-ARM has been shown to facilitate the identification of ultra-slow anal waves 37 (Fig. 6F).

Furthermore, these techniques may play a role in the assessment of anatomical changes; in this respect, HD-ARM has been shown to be useful for the diagnosis of sphincter disorders when compared to endoanal ultrasound 38,39. Similarly, HR-ARM and HD-ARM may be useful for the diagnosis of pelvic floor disorders including descending perineum syndrome 40,41, rectal prolapse and intussusception (Fig. 3D) when compared to fluoroscopy or MRI defecography 42,43,44. However, no correlation has been found between resting pressure and voluntary contraction pressure, and internal or external anal sphincter thickness, respectively, using HD-ARM and 3D ultrasound 45. HD-ARM has shown that anal canal relaxation with rectal ampulla distension varies along the canal's length, with maximum changes proximal to the internal anal sphincter 46.

However, no additional benefits over the standard technique have been found for the study of fecal incontinence, and its role in discriminating healthy individuals from dyssynergic defecation patients has been questioned 21,25,47 to the point of doubting the actual contribution of this technology (48). This may be due, at least partly, to our using conventional metrics in HR-ARM, as newer parameters should be assessed with this approach 49. For instance, a phenotype classification has been suggested, which is difficult to apply in clinical practice 50.

Fig. 3 Transient anal sphincter relaxations, anal ultra-slow waves, and rectal intussusception identified by high-resolution and high-definition manometry. Transient anal sphincter relaxations identified with conventional line tracings (A) and high-resolution topography (B) in a patient with fecal incontinence. During the defecatory maneuver line tracings (C) fail to identify the presence of rectal intussusception, whereas the 3D reconstruction of high-definition manometry clearly reveals its presence (D). Presence of ultra-slow anal waves at rest, detected by pressure line tracings (E) and topography (F) in a patient with proctalgia fugax (original images). 

Table 2 Normal anal canal pressures and defecatory maneuver parameters as measured with a 256-sensor HD-ARM catheter (Medtronic) 

( ) 95% confidence interval; *p < 0.05 versus males; ND: no data.

In an attempt to discriminate healthy individuals from fecal incontinence patients a voluntary contraction profile has been described for HR-ARM; this parameter integrates the product of mean pressure increase, sphincter length, and voluntary contraction duration (mmHg.cm.5s), and increases sensitivity to fecal incontinence by 59% as compared to conventional metrics 51.

Newer HR-ARM- and HD-ARM-specific parameters have also been reported to better discriminate between dyssynergic defecation patients and healthy individuals, including the anal contractile integrated, post-contraction pressure, anal integrated relaxation pressure, and sliding velocity in the anal canal. In a study in 40 healthy volunteers (28 women, mean age 35 years) and 20 patients with dyssynergic defecation (12 women, mean age 46 years), the latter exhibited significantly different values as compared to the former in each of the above parameters, suggesting that said parameters are able to tell normalcy from pathology 52. Integrated pressurized volume (IPV) has been recently posited - it is measured in the anal canal and rectum to calculate the IPV ratio, a parameter already used in high-resolution esophageal manometry, and its correlation with balloon expulsion testing. This measurement may better predict delays in the balloon expulsion test in comparison with conventional parameters 53,54.

While the newly-posited measurements are promising, and will likely help us advance in the recognition of functional anorectal disorders, as was the case with high-resolution esophageal manometry, further studies including higher numbers of healthy individuals and patients are required for their validation. Similarly, these promising "anatomic data" require a review, possibly a classification, of pelvic disorders as defined with HR-ARM.

To conclude, HR-ARM and HD-ARM are more intuitive and easier to perform than the standard technique, and represent an aid to better understand anorectal physiology by allowing correlation between anatomy and function, as well as the pathophysiology of functional anorectal conditions. These technologies permit the assessment of spontaneous activity in the anal canal, which is difficult to evaluate using the conventional technique, and are highly promising for the assessment of anatomic changes in the anal canal and pelvic floor. Their development is slower as compared to high-resolution esophageal manometry, and here a control arm is required with larger numbers of well-selected healthy individuals, including a variety of age, gender, parity status, and probably ethnics groups. Furthermore, it is key that properly standardized reference values be available, both for solid-state and perfusion systems. Consensus and validation are also important for novel measurement parameters specific of high-resolution manometry in order to enhance its diagnostic yield in the study of both motor and functional anorectal disorders.

BIBLIOGRAFÍA

1. Remes-Troche JM, Rao SS. Defecation disorders: neuromuscular aspects and treatment. Curr Gastroenterol Rep. 2006;8(4):291-9. DOI: 10.1007/s11894-006-0049-x [ Links ]

2. Whitehead WE, Wald A, Diamant NE, et al. Functional disorders of the anus and rectum. Gut 1999;45(Suppl. 2):55-9. DOI: 10.1136/gut.45.2008.ii55 [ Links ]

3. Diamant NE, Kamm M, Wald A, et al. AGA technical review on anorectal testing techniques. Gastroenterology 1999;116(3):735-60. DOI: 10.1016/S0016-5085(99)70195-2 [ Links ]

4. Bharucha AE, Rao SS. An update on anorectal disorders for gastroenterologists. Gastroenterology 2014;146(1):37-45 e2. DOI: 10.1053/j.gastro.2013.10.062 [ Links ]

5. Rao SS. Advances in diagnostic assessment of fecal incontinence and dyssynergic defecation. Clin Gastroenterol Hepatol 2010;8(11):910-9. DOI: 10.1016/j.cgh.2010.06.004 [ Links ]

6. Amieva-Balmori M, Remes Troche J. Pruebas neurofisiológicas en trastornos anorrectales. Acta Gastroenterol Latinoam 2015;45(3):252-62. [ Links ]

7. Lee YY, Erdogan A, Rao SS. High resolution and high definition anorectal manometry and pressure topography: diagnostic advance or a new kid on the block? Curr Gastroenterol Rep 2013;15(12):360. DOI: 10.1007/s11894-013-0360-2 [ Links ]

8. Vitton V, Ben Hadj Amor W, Baumstarck K, et al. Water-perfused manometry vs three-dimensional high-resolution manometry: a comparative study on a large patient population with anorectal disorders. Colorectal Dis 2013;15(12):e726-31. DOI: 10.1111/codi.12397 [ Links ]

9. Benezech A, Behr M, Bouvier M, et al. Three-dimensional high-resolution anorectal manometry: does it allow automated analysis of sphincter defects? Colorectal Dis 2015;17(10):O202-7. DOI: 10.1111/codi.13017 [ Links ]

10. Ciriza-de-los-Ríos C, Ruiz-de-León A. Manometría anorrectal de alta resolución. En: Lacima G, Serra J, Mínguez M, Accarino A, editores. Tratado de Neurogastroenterología y Motilidad Digestiva. 1. Madrid: Panamericana; 2014. pp. 624-35. [ Links ]

11. Mínguez Pérez M, Lacima Vidal G. Manometría anorrectal convencional. In: Lacima G, Serra J, Mínguez M, Accarino A, editores. Tratado de Neurogastroenterología y Motilidad Digestiva. 3. Madrid: Panamericana; 2014. pp. 613-23. [ Links ]

12. Sauter M, Heinrich H, Fox M, et al. Toward more accurate measurements of anorectal motor and sensory function in routine clinical practice: validation of high-resolution anorectal manometry and Rapid Barostat Bag measurements of rectal function. Neurogastroenterol Motil 2014;26(5):685-95. DOI: 10.1111/nmo.12317 [ Links ]

13. Lee TH, Bharucha AE. How to Perform and Interpret a High-resolution Anorectal Manometry Test. J Neurogastroenterol Motil 2016;22(1):46-59. [ Links ]

14. Rasijeff AMP, Withers M, Burke JM, et al. High-resolution anorectal manometry: A comparison of solid-state and water-perfused catheters. Neurogastroenterol Motil 2017;29(11). DOI: 10.1111/nmo.13124 [ Links ]

15. Chakraborty S, Feuerhak KJ, Zinsmeister AR, et al. Reproducibility of high-definition (3D) manometry and its agreement with high-resolution (2D) manometry in women with fecal incontinence. Neurogastroenterol Motil 2017;29(3). doi: 10.1111/nmo.12950 [ Links ]

16. Kang HR, Lee JE, Lee JS, et al. Comparison of High-resolution Anorectal Manometry With Water-perfused Anorectal Manometry. J Neurogastroenterol Motil 2015;21(1):126-32. DOI: 10.5056/jnm14025 [ Links ]

17. Li Y, Yang X, Xu C, et al. Normal values and pressure morphology for three-dimensional high-resolution anorectal manometry of asymptomatic adults: a study in 110 subjects. Int J Colorectal Dis 2013;28(8):1161-8. DOI: 10.1007/s00384-013-1706-9 [ Links ]

18. Carrington EV, Scott SM, Bharucha A, et al. Advances in the evaluation of anorectal function. International Anorectal Physiology Working Group and the International Working Group for Disorders of Gastrointestinal Motility and Function. Expert consensus document : Advances in the evaluation of anorectal function. Nat Rev Gastroenterol Hepatol 2018;15:309-23. doi: 10.1038/nrgastro.2018.27 [ Links ]

19. Noelting J, Ratuapli SK, Bharucha AE, et al. Normal values for high-resolution anorectal manometry in healthy women: effects of age and significance of rectoanal gradient. Am J Gastroenterol 2012;107(10):1530-6. DOI: 10.1038/ajg.2012.221 [ Links ]

20. Carrington EV, Brokjaer A, Craven H, et al. Traditional measures of normal anal sphincter function using high-resolution anorectal manometry (HRAM) in 115 healthy volunteers. Neurogastroenterol Motil 2015;26(5):625-35. DOI: 10.1111/nmo.12307 [ Links ]

21. Coss-Adame E, Rao S, Valestin J, et al. Accuracy and Reproducibility of High-definition Anorectal Manometry and Pressure Topography Analyses in Healthy Subjects. Clin Gastroenterol Hepatol 2015;13(6):1143-50. DOI: 10.1016/j.cgh.2014.12.034 [ Links ]

22. Lee HJ, Jung KW, Han S, et al. Normal values for high-resolution anorectal manometry/topography in a healthy Korean population and the effects of gender and body mass index. Neurogastroenterol Motil 2014;26(4):529-37. DOI: 10.1111/nmo.12297 [ Links ]

23. Opazo A, Aguirre E, Saldana E, et al. Patterns of impaired internal anal sphincter activity in patients with anal fissure. Colorectal Dis 2013; 15(4):492-9. DOI: 10.1111/codi.12095 [ Links ]

24. Prichard D, Harvey DM, Fletcher JG, et al. Relationship Among Anal Sphincter Injury, Patulous Anal Canal, and Anal Pressures in Patients With Anorectal Disorders. Clin Gastroenterol Hepatol 2015;13(10):1793-800 e1. DOI: 10.1016/j.cgh.2015.03.033 [ Links ]

25. Grossi U, Carrington EV, Bharucha AE, et al. Diagnostic accuracy study of anorectal manometry for diagnosis of dyssynergic defecation. Gut 2016;66:447-55. DOI: 10.1136/gutjnl-2014-308835 [ Links ]

26. Rao SS, Kavlock R, Rao S. Influence of body position and stool characteristics on defecation in humans. Am J Gastroenterol 2006;10(12):2790-6. DOI: 10.1111/j.1572-0241.2006.00827.x [ Links ]

27. Ratuapli S, Bharucha AE, Harvey D, et al. Comparison of rectal balloon expulsion test in seated and left lateral positions. Neurogastroenterol Motil 2013;25(12):e813-20. DOI: 10.1111/nmo.12208 [ Links ]

28. Rao SSC, Mudipalli RS, Stessman M, et al. Investigation of the utility of colorectal function tests and Rome II criteria in dyssynergic defecation (Anismus). Neurogastroenterol Motil 2004;16:589-96. DOI: 10.1111/j.1365-2982.2004.00526.x [ Links ]

29. Rao SS, Patcharatrakul T. Diagnosis and Treatment of Dyssynergic Defecation. J Neurogastroenterol Motil 2016;22(3):423-35. DOI: 10.5056/jnm16060 [ Links ]

30. Lee YY, Erdogan A, Yu S, et al. Anorectal Manometry in Defecatory Disorders: A Comparative Analysis of High-resolution Pressure Topography and Waveform Manometry. J Neurogastroenterol Motil 2018;24(3):460-8. DOI: 10.5056/jnm17081 [ Links ]

31. Mion F, Garros A, Brochard C, et al. 3D High-definition anorectal manometry: Values obtained in asymptomatic volunteers, fecal incontinence and chronic constipation. Results of a prospective multicenter study (NOMAD). Neurogastroenterol Motil 2017;29(8). DOI: 10.1111/nmo.13049 [ Links ]

32. Vitton V, Ben Hadj Amor W, et al. Comparison of three-dimensional high-resolution manometry and endoanal ultrasound in the diagnosis of anal sphincter defects. Colorectal Dis 2013;15(10):e607-11. DOI: 10.1111/codi.12319 [ Links ]

33. Raizada V, Bhargava V, Karsten A, et al. Functional morphology of anal sphincter complex unveiled by high definition anal manometery and three dimensional ultrasound imaging. Neurogastroenterol Motil 2011;23(11):1013-9. DOI: 10.1111/j.1365-2982.2011.01782.x [ Links ]

34. Ambartsumyan L, Rodríguez L, Morera C, et al. Longitudinal and radial characteristics of intra-anal pressures in children using 3D high-definition anorectal manometry: new observations. Am J Gastroenterol 2013;108(12):1918-28. DOI: 10.1038/ajg.2013.361 [ Links ]

35. Xu C, Zhao R, Conklin JL, et al. Three-dimensional high-resolution anorectal manometry in the diagnosis of paradoxical puborectalis syndrome compared with healthy adults: a retrospective study in 79 cases. Eur J Gastroenterol Hepatol 2014;26(6):621-9. DOI: 10.1097/MEG.0000000000000059 [ Links ]

36. Carrington EV, Hobson A, Knowles CH, et al. Characterization of Transient Anal Sphincter Relaxations (TASRs) Health Using High Resolution Anorectal Manometry: Redefining the Sampling Reflex? Gastroenterology 2013;144(Suppl. 1):S745. DOI: 10.1016/S0016-5085(13)62761-4 [ Links ]

37. Remes-Troche JM, Roesch FB, Azamar-Jacome A. Topography and Characterization of Anal Ultraslow Waves (AUSWs) in Patients With Proctalgia Fugax. a Study Using High-Definition Anorectal Manometry (HDM). Gastroenterology 2012;143;5(Suppl. 1):905. [ Links ]

38. Raja S, Okeke FC, Stein EM, et al. Three-Dimensional Anorectal Manometry Enhances Diagnostic Gain by Detecting Sphincter Defects and Puborectalis Pressure. Dig Dis Sci 2017;62(12):3536-41. DOI: 10.1007/s10620-017-4466-5 [ Links ]

39. Rezaie A, Iriana S, Pimentel M, et al. Can three-dimensional high-resolution anorectal manometry detect anal sphincter defects in patients with faecal incontinence? Colorectal Dis 2017;19(5):468-75. DOI: 10.1111/codi.13530 [ Links ]

40. Vitton V, Grimaud JC, Bouvier M. Three-dimension High-resolution Anorectal Manometry Can Precisely Measure Perineal Descent. J Neurogastroenterol Motil 2013;19(2):257-8. DOI: 10.5056/jnm.2013.19.2.257 [ Links ]

41. Benezech A, Bouvier M, Grimaud JC, et al. Three-dimensional high-resolution anorectal manometry and diagnosis of excessive perineal descent: a comparative pilot study with defaecography. Colorectal Dis 2014;16(5):O170-5. DOI: 10.1111/codi.12522 [ Links ]

42. Benezech A, Cappiello M, Baumstarck K, et al. Rectal intussusception: can high resolution three-dimensional ano-rectal manometry compete with conventional defecography? Neurogastroenterol Motil 2017;29(4). DOI: 10.1111/nmo.12978 [ Links ]

43. Heinrich H, Sauter M, Fox M, et al. Assessment of Obstructive Defecation by High-Resolution Anorectal Manometry Compared With Magnetic Resonance Defecography. Clin Gastroenterol Hepatol 2015;13(7):1310-7.e1. [ Links ]

44. Prichard DO, Lee T, Parthasarathy G, et al. High-resolution Anorectal Manometry for Identifying Defecatory Disorders and Rectal Structural Abnormalities in Women. Clin Gastroenterol Hepatol 2017;15(3):412-20. DOI: 10.1016/j.cgh.2016.09.154 [ Links ]

45. Wickramasinghe DP, Perera CS, Senanayake H, et al. Correlation of three dimensional anorectal manometry and three dimensional endoanal ultrasound findings in primi gravida: a cross sectional study. BMC Res Notes 2015;8:387-93. DOI: 10.1186/s13104-015-1346-y [ Links ]

46. Cheeney G, Nguyen M, Valestin J, et al. Topographic and manometric characterization of the recto-anal inhibitory reflex. Neurogastroenterol Motil 2012;24(3):e147-54. DOI: 10.1111/j.1365-2982.2011.01857.x [ Links ]

47. Dinning PG, Carrington EV, Scott SM. Colonic and anorectal motility testing in the high-resolution era. Curr Opin Gastroenterol 2016;32(1):44-8. DOI: 10.1097/MOG.0000000000000229 [ Links ]

48. Basilisco G, Bharucha AE. High-resolution anorectal manometry: An expensive hobby or worth every penny? Neurogastroenterol Motil 2017;29(8). DOI: 10.1111/nmo.13125 [ Links ]

49. Vitton V, Benezech A, Bouvier M. High-resolution anorectal manometry may probably be worth every penny. Neurogastroenterol Motil 2018;30(1). DOI: 10.1111/nmo.13217 [ Links ]

50. Ratuapli SK, Bharucha AE, Noelting J, et al. Phenotypic identification and classification of functional defecatory disorders using high-resolution anorectal manometry. Gastroenterology 2013;144(2):314-22.e2. DOI: 10.1053/j.gastro.2012.10.049 [ Links ]

51. Carrington EV, Knowles CH, Grossi U, et al. High-resolution Anorectal Manometry Measures are More Accurate Than Conventional Measures in Detecting Anal Hypocontractility in Women With Fecal Incontinence. Clin Gastroenterol Hepatol 2018;pii:S1542-3565(18)30694-3. doi: 10.1016/j.cgh.2018.06.037. [ Links ]

52. Remes Troche JM, Pérez Luna E, Reyes Huerta JU, et al. Development of New Parameters to Evaluate Anorectal Function Using High-Definition Anorectal Manometry (HDM). the Anal Contractile Integrated (ACI), the Post Squeeze Pressure (PSP), the Anal Integrated Relaxation Pressure (aIRP), and the Sliding Velocity in the Anal Canal (SVAC). Gastroenterology 2013;144(5):S365. DOI: 10.1016/S0016-5085(13)61343-8 [ Links ]

53. Jung KW, Joo S, Yang DH, et al. A novel high-resolution anorectal manometry parameter based on a three-dimensional integrated pressurized volume of a spatiotemporal plot, for predicting balloon expulsion in asymptomatic normal individuals. Neurogastroenterol Motil 2014;26(7):937-49. [ Links ]

54. Seo M, Joo S, Jung KW, et al. A high-resolution anorectal manometry parameter based on integrated pressurized volume: A study based on 204 male patients with constipation and 26 controls. Neurogastroenterol Motil 2018;e13376. doi: 10.1111/nmo.13376 [ Links ]

Received: May 08, 2018; Accepted: September 11, 2018

Correspondence: Constanza Ciriza-de-los-Ríos. Digestive Motility Unit. Department of Digestive Diseases. Hospital Universitario 12 de Octubre. Avda. de Córdoba, s/n. 28041 Madrid, Spain. e-mail: constanzacarpa@gmail.com

Creative Commons License Este es un artículo publicado en acceso abierto bajo una licencia Creative Commons