The work was funded by NSF CAREER award grant #1751050.

The protocol provided in this article presents a method for determining the mechanical properties of the murine vagina and cervix. The mechanical properties analyzed in this protocol include both the passive and basal tone conditions of the organs. Passive and basal tone conditions are induced by altering the biochemical environment in which the organ is submerged. For this protocol, the media involved in basal testing contains calcium. Testing the basal tone condition permits isolation of the smooth muscle cell mechanic...

The vaginal wall is composed of four layers, the epithelium, lamina propria, muscularis, and adventitia. The epithelium is primarily composed of epithelial cells. The lamina propria has a large amount of elastic and fibrillar collagen fibers. The muscularis is also composed of elastin and collagen fibers but has an increased amount of smooth muscle cells. The adventitia is comprised of elastin, collagen, and fibroblasts, albeit in reduced concentrations compared to the previous layers. The smooth muscle cells are of interest to biomechanically motivated research groups as they play a role in the contractile nature of the organs. As such, quantifying the smooth muscle cell area fraction and organization is key to understanding the mechanical function. Previous investigations suggest that the smooth muscle content within the vaginal wall is primarily organized in the circumferential and longitudinal axis. Histological analysis suggests that the smooth muscle area fraction is approximately 35% for both the proximal and distal sections of the wall1.
The cervix is a highly collagenous structure, that until recently, was thought to have minimal smooth muscle cell content2,3. Recent studies, however, have suggested that smooth muscle cells may have a greater abundance and role in the cervix4,5. The cervix exhibits a gradient of smooth muscle cells. The internal os contains 50-60% smooth muscle cells where the external os only contains 10%. Mouse studies, however, report the cervix to be composed of 10-15% smooth muscle cells and 85-90% fibrous connective tissue with no mention of regional differences6,7,8. Given that the mouse model differs from the frequently reported human model, further investigations concerning the mouse cervix are needed.
The purpose of this protocol was to elucidate the mechanical properties of the murine vagina and cervix. This was accomplished by using a pressure myograph device that enables assessment of mechanical properties in the circumferential and axial directions simultaneously while maintaining native cell-matrix interactions and organ geometry. The organs were mounted on two custom cannulas and secured with silk 6-0 sutures. Pressure-diameter tests were performed around the estimated physiological axial stretch to determine the compliance and tangent moduli9. Force-length tests were conducted to confirm the estimated axial stretch and to ensure that mechanical properties were quantified in the physiological range. The experimental protocol was performed on the nonpregnant murine vagina and cervix at 4-6 months of age in estrus.
The protocol is divided into two main mechanical testing sections: basal tone and passive testing. A basal tone is defined as the baseline partial constriction of smooth muscle cells, even in the absences of external local, hormonal, and neural stimulation10. This baseline contractile nature of the vagina and cervix yields characteristic mechanical behaviors which are then measured by the pressure myograph system. The passive properties are assessed by removing the intercellular calcium that maintains the baseline state of contraction, resulting in relaxation of the smooth muscle cells. In the passive state, collagen and elastin fibers provide the dominant contributions for the mechanical characteristics of the organs.
The murine model is used extensively to study pathologies in women&#8217;s reproductive health. The mouse offers several advantages for quantifying the evolving relationships between ECM and mechanical properties within the reproductive system11,12,13,14. These advantages include short and well-characterized estrous cycles, relatively low cost, ease of handling, and a relatively short gestational time15. Additionally, the genome of laboratory mice is well-mapped and genetically-modified mice are valuable tools to test mechanistic hypotheses16,17,18.
Commercially available pressure myograph systems are used extensively to quantify the mechanical responses of various tissues and organs. Some notable structures analyzed on the pressure myograph system include elastic arteries19,20,21,22, veins and tissue engineered vascular grafts23,24, the esophagus25, and the large intestines26. The pressure myograph technology permits simultaneous assessment of properties in the axial and circumferential directions while maintaining the native cell-ECM interactions and in vivo geometry. Despite the extensive use of myograph systems in soft tissue and organ mechanics, a protocol utilizing the pressure myograph technology had not previously been developed for the vagina and cervix. Prior investigations into the mechanical properties of the vagina and cervix were assessed uniaxially27,28. These organs, however, experience multiaxial loading within the body29,30, thus quantifying their biaxial mechanical response is important.
Moreover, recent work suggests smooth muscle cells may play a potential role in soft tissue pathologies5,28,31,32. This provides another attraction of utilizing the pressure myograph technology, as it preserves the native cell-matrix interactions, thus permitting delineation of the contribution that smooth muscle cells play in physiological and pathophysiological conditions. Herein, we propose a protocol to quantify the multiaxial mechanical properties of the vagina and cervix under both basal tone and passive conditions.

<table><tbody><tr><td>2F catheter</td><td>Millar</td><td>SPR-320</td><td>catheter to measure cervical pressure</td></tr><tr><td>6-0 Suture</td><td>Fine Science Tools</td><td>18020-60</td><td>larger suture ties</td></tr><tr><td>CaCl2 (anhydrous)</td><td>VWR</td><td>97062-590</td><td>HBSS concentration: 140 mg/ mL</td></tr><tr><td>CaCl2-2H20</td><td>Fischer chemical</td><td>BDH9224-1KG</td><td>&lt;br/&gt; KRB concentration: 3.68 g/L</td></tr><tr><td>Dextrose (D-glucose)</td><td>VWR</td><td>101172-434</td><td>HBSS concentration: 1000 mg/mL&lt;br/&gt; KRB concentration: 19.8 g/L</td></tr><tr><td>Dumont #5/45 Forceps</td><td>Fine Science Tools</td><td>11251-35</td><td>curved forceps</td></tr><tr><td>Dumont SS Forceps</td><td>Fine Science Tools</td><td>11203-25</td><td>straight forceps</td></tr><tr><td>Eclipse</td><td>Nikon</td><td>E200</td><td>microscope used for imaging</td></tr><tr><td>Flow meter</td><td>Danish MyoTechnologies</td><td>161FM</td><td>flow meter within the testing apparatus</td></tr><tr><td>Force Transducer - 110P</td><td>Danish MyoTechnologies</td><td>100079</td><td>force transducer</td></tr><tr><td>ImageJ</td><td>SciJava</td><td>ImageJ1</td><td>used to measure volume</td></tr><tr><td>Instrument Cases</td><td>Fine Science Tools</td><td>20830-00</td><td>casing to hold dissection tools</td></tr><tr><td>KCl</td><td>Fisher Chemical</td><td>97061-566</td><td>HBSS concentration: 400 mg/ mL&lt;br/&gt; KRB concentration: 3.5 g/L</td></tr><tr><td>KH2PO4</td><td>G-Biosciences</td><td>71003-454</td><td>HBSS concentration: 60 mg/ mL</td></tr><tr><td>MgCl2</td><td>VWR</td><td>97064-150</td><td>&lt;br/&gt; KRB concentration: 1.14 g/L</td></tr><tr><td>MgCl2-6H2O</td><td>VWR</td><td>BDH9244-500G</td><td>HBSS concentration: 100 mg/ mL</td></tr><tr><td>MgSO4-7H20</td><td>VWR</td><td>97062-134</td><td>HBSS concentration: 48 mg/ mL</td></tr><tr><td>Mircosoft excel</td><td>Microsoft</td><td>6278402</td><td>program used for spreadsheet</td></tr><tr><td>Na2HPO4 (dibasic anhydrous)</td><td>VWR</td><td>97061-588</td><td>HBSS concentration: 48 mg/mL&lt;br/&gt; KRB concentration: 1.44 g/L</td></tr><tr><td>NaCl</td><td>VWR</td><td>97061-274</td><td>HBSS concentration: 8000 mg/mL&lt;br/&gt; KRB concentration: 70.1 g/L</td></tr><tr><td>NaHCO3</td><td>VWR</td><td>97062-460</td><td>HBSS concentration: 350 mg/ mL&lt;br/&gt; KRB concentration: 21.0 g/L</td></tr><tr><td>Pressure myograph systems</td><td>Danish MyoTechnologies</td><td>110P and 120CP</td><td>Pressure myograph system:&lt;br/&gt; prorgram, cannulation device,&lt;br/&gt; and controller unit</td></tr><tr><td>Pressure Transducer</td><td>Danish MyoTechnologies</td><td>100106</td><td>pressure transducer</td></tr><tr><td>Student Dumont #5 Forceps</td><td>Fine Science Tools</td><td>91150-20</td><td>straight forceps</td></tr><tr><td>Student Vannas Spring Scissors</td><td>Fine Science Tools</td><td>91500-09</td><td>micro-scissors</td></tr><tr><td>Tissue dye</td><td>Bradley Products</td><td>1101-3</td><td>ink to measure in vivo stretch</td></tr><tr><td>Ultrasound transducer</td><td>FujiFilm Visual Sonics</td><td>LZ-550</td><td>ultrasound transducer used; 256 elements, 40 MHz center frequency</td></tr><tr><td>VEVO2100</td><td>FujiFilm Visual Sonics</td><td>VS-20035</td><td>ultrasound used for imaging</td></tr><tr><td>Wagner Scissors</td><td>Fine Science Tools</td><td>14069-12</td><td>larger scissors</td></tr></tbody></table>

biaxial basal tone and passive testing of the murine reproductive system using a pressure myograph

The female reproductive organs, specifically the vagina and cervix, are composed of various cellular components and a unique extracellular matrix (ECM). Smooth muscle cells exhibit a contractile function within the vaginal and cervical walls. Depending on the biochemical environment and the mechanical distension of the organ walls, the smooth muscle cells alter the contractile conditions. The contribution of the smooth muscle cells under baseline physiological conditions is classified as a basal tone. More specifically, a basal tone is the baseline partial constriction of smooth muscle cells in the absence of hormonal and neural stimulation. Furthermore, the ECM provides structural support for the organ walls and functions as a reservoir for biochemical cues. These biochemical cues are vital to various organ functions, such as inciting growth and maintaining homeostasis. The ECM of each organ is composed primarily of collagen fibers (mostly collagen types I, III, and V), elastic fibers, and glycosaminoglycans/proteoglycans. The composition and organization of the ECM dictate the mechanical properties of each organ. A change in ECM composition may lead to the development of reproductive pathologies, such as pelvic organ prolapse or premature cervical remodeling. Furthermore, changes in ECM microstructure and stiffness may alter smooth muscle cell activity and phenotype, thus resulting in the loss of the contractile force.
In this work, the reported protocols are used to assess the basal tone and passive mechanical properties of the nonpregnant murine vagina and cervix at 4-6 months of age in estrus. The organs were mounted in a commercially available pressure myograph and both pressure-diameter and force-length tests were performed. Sample data and data analysis techniques for the mechanical characterization of the reproductive organs are included. Such information may be useful for constructing mathematical models and rationally designing therapeutic interventions for women&#8217;s health pathologies.

Successful analysis of the mechanical properties of the female reproductive organs is contingent on appropriate organ dissection, cannulation, and testing. It is imperative to explant the uterine horns to the vagina without any defects (Figure 1). Depending on the organ type, the cannula size will vary (Figure 2). Cannulation must be done so that the organ cannot move during the experiment but also not damage the wall of the organ during the procedure (Figure 3</...

Watch this Scientific Journal Video about Biaxial Basal Tone and Passive Testing of the Murine Reproductive System Using a Pressure Myograph at JoVE.com

Biaxial Basal Tone and Passive Testing of the Murine Reproductive System Using a Pressure Myograph

This protocol utilized a commercially available pressure myograph system to perform pressure myograph testing on the murine vagina and cervix. Utilizing media with and without calcium, the contributions of the smooth muscle cells (SMC) basal tone and passive extracellular matrix (ECM) were isolated for the organs under estimated physiological conditions.

The female reproductive organs, specifically the vagina and cervix, are composed of various cellular components and a unique extracellular matrix (ECM). ...

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Research

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Bioengineering

9.4K Views.  Tulane University. This protocol utilized a commercially available pressure myograph system to perform pressure myograph testing on the murine vagina and cervix. Utilizing media with and without calcium, the contributions of the smooth muscle cells (SMC) basal tone and passive extracellular matrix (ECM) were isolated for the organs under estimated physiological conditions.

Video: Biaxial Basal Tone and Passive Testing of the Murine Reproductive System Using a Pressure Myograph

Measuring Left Ventricular Pressure in Late Embryonic and Neonatal Mice

Blood pressure increases significantly during embryonic and postnatal development in vertebrate animals. In the mouse, blood flow is first detectable around embryonic day (E) 8.51. Systolic left ventricular (LV) pressure is 2 mmHg at E9.5 and 11 mmHg at E14.52. At these mid-embryonic stages, the LV is clearly visible through the chest wall for invasive pressure measurements because the ribs and skin are not fully developed. Between E14.5 and birth (approximately E21) imaging methods must be used to view the LV. After birth, mean arterial pressure increases from 30 - 70 mmHg from postnatal day (P) 2 - 353. Beyond P20, arterial pressure can be measured with solid-state catheters (i.e. Millar or Scisense). Before P20, these catheters are too big for developing mouse arteries and arterial pressure must be measured with custom pulled plastic catheters attached to fluid-filled pressure transducers3 or glass micropipettes attached to servo null pressure transducers4.
Our recent work has shown that the greatest increase in blood pressure occurs during the late embryonic to early postnatal period in mice5-7. This large increase in blood pressure may influence smooth muscle cell (SMC) phenotype in developing arteries and trigger important mechanotransduction events. In human disease, where the mechanical properties of developing arteries are compromised by defects in extracellular matrix proteins (i.e. Marfan's Syndrome8 and Supravalvular Aortic Stenosis9) the rapid changes in blood pressure during this period may contribute to disease phenotype and severity through alterations in mechanotransduction signals. Therefore, it is important to be able to measure blood pressure changes during late embryonic and neonatal periods in mouse models of human disease.
We describe a method for measuring LV pressure in late embryonic (E18) and early postnatal (P1 - 20) mice. A needle attached to a fluid-filled pressure transducer is inserted into the LV under ultrasound guidance. Care is taken to maintain normal cardiac function during the experimental protocol, especially for the embryonic mice. Representative data are presented and limitations of the protocol are discussed.

Measuring left ventricular pressure (LV) in embryonic and neonatal mice is described. Pressure is measured by inserting a needle connected to a fluid-filled transducer into the LV under ultrasound guidance. Care must be taken to maintain normal cardiac function during the experimental protocol.

Blood pressure increases significantly during embryonic and postnatal development in vertebrate animals. In the mouse, blood flow is first detectable ...

Measurement of Tactile Allodynia in a Murine Model of Bacterial Prostatitis

Uropathogenic Escherichia coli (UPEC) are pathogens that play an important role in urinary tract infections and bacterial prostatitis1. We have recently shown that UPEC have an important role in the initiation of chronic pelvic pain2, a feature of Chronic prostatitis/Chronic pelvic pain syndrome (CP/CPPS)3,4. Infection of the prostate by clinically relevant UPEC can initiate and establish chronic pain through mechanisms that may involve tissue damage and the initiation of mechanisms of autoimmunity5.
A challenge to understanding the pathogenesis of UPEC in the prostate is the relative inaccessibility of the prostate gland to manipulation. We utilized a previously described intraurethral infection method6 to deliver a clinical strain of UPEC into male mice thereby establishing an ascending infection of the prostate. Here, we describe our protocols for standardizing the bacterial inoculum7 as well as the procedure for catheterizing anesthetized male mice for instillation of bacteria.
CP/CPPS is primarily characterized by the presence of tactile allodynia4. Behavior testing was based on the concept of cutaneous hyperalgesia resulting from referred visceral pain8-10. An irritable focus in visceral tissues reduces cutaneous pain thresholds allowing for an exaggerated response to normally non-painful stimuli (allodynia). Application of normal force to the skin result in abnormal responses that tend to increase with the intensity of the underlying visceral pain. We describe methodology in NOD/ShiLtJ mice that utilize von Frey fibers to quantify tactile allodynia over time in response to a single infection with UPEC bacteria.

Infection of the prostate may be a contributing factor in mediating pelvic pain in chronic prostatitis. We describe the procedure for preparation of standardized bacterial inoculum, instillation of bacteria into the urethra of male mice and methodology for measuring tactile allodynia in mice over time.

Uropathogenic Escherichia coli (UPEC) are pathogens that play an important role in urinary tract infections and bacterial prostatitis1. We have recently ...

Immunology and Infection

Back Mechanical Sensitivity Assessment in the Rat for Mechanistic Investigation of Chronic Back Pain

Low back pain is the leading cause of disability worldwide, with dramatic personal, economic, and social consequences. To develop novel therapeutics, animal models are needed to examine the mechanisms and effectiveness of novel therapies from a translational perspective. Several rodent models of back pain are used in current investigations. Surprisingly, however, no standardized behavioral test was validated to assess mechanical sensitivity in back pain models. This is critical to confirm that animals with presumed back pain present local hypersensitivity to nociceptive stimuli, and to monitor sensitivity during interventions designed to relieve back pain. The objective of this study is to lay down a simple and accessible test to assess mechanical sensitivity in the back of rats. A test cage was fabricated specifically for this method; length x width x height: 50 x 20 x 7 cm, having a stainless-steel mesh on the top. This test cage allows the application of mechanical stimuli to the back. To perform the test, the back of the animal is shaved in the region of interest, and the test area is marked to repeat the test on different days, as needed. The mechanical threshold is determined with Von Frey filaments applied to the paraspinal muscles, utilizing the up-down method described previously. The positive responses include (1) muscle twitching, (2) arching (back extension), (3) rotation of the neck (4) scratching or licking the back, and (5) escaping. This behavioral test (Back Mechanical Sensitivity (BMS) test) is useful for mechanistic research with rodent models of back pain for the development of therapeutic interventions for the prevention and management of back pain.

To develop novel therapeutic interventions for the prevention and management of back pain, animal models are required to examine the mechanisms and effectiveness of these therapies from a translational perspective. The present protocol describes the BMS test, a standardized method to assess back mechanical sensitivity in the rat.

Low back pain is the leading cause of disability worldwide, with dramatic personal, economic, and social consequences. To develop novel therapeutics, ...

Behavior

Intrauterine Telemetry to Measure Mouse Contractile Pressure In Vivo

A complex integration of molecular and electrical signals is needed to transform a quiescent uterus into a contractile organ at the end of pregnancy. Despite the discovery of key regulators of uterine contractility, this process is still not fully understood. Transgenic mice provide an ideal model in which to study parturition. Previously, the only method to study uterine contractility in the mouse was ex vivo isometric tension recordings, which are suboptimal for several reasons. The uterus must be removed from its physiological environment, a limited time course of investigation is possible, and the mice must be sacrificed. The recent development of radiometric telemetry has allowed for longitudinal, real-time measurements of in vivo intrauterine pressure in mice. Here, the implantation of an intrauterine telemeter to measure pressure changes in the mouse uterus from mid-pregnancy until delivery is described. By comparing differences in pressures between wild type and transgenic mice, the physiological impact of a gene of interest can be elucidated. This technique should expedite the development of therapeutics used to treat myometrial disorders during pregnancy, including preterm labor.

Intrauterine Telemetry to Measure Mouse Contractile Pressure In Vivo

This manuscript provides a protocol for implanting telemeters in the mouse for the purpose of measuring intrauterine pressures during pregnancy.

A complex integration of molecular and electrical signals is needed to transform a quiescent uterus into a contractile organ at the end of pregnancy. ...

Medicine

Assessment of Perigenital Sensitivity and Prostatic Mast Cell Activation in a Mouse Model of Neonatal Maternal Separation

Chronic prostatitis/chronic pelvic pain syndrome (CP/CPPS) has a lifetime prevalence of 14% and is the most common urological diagnosis for men under the age of 50, yet it is the least understood and studied chronic pelvic pain disorder. A significant subset of patients with chronic pelvic pain report having experienced early life stress or abuse, which can markedly affect the functioning and regulation of the hypothalamic-pituitary-adrenal (HPA) axis. Mast cell activation, which has been shown to be increased in both urine and expressed prostatic secretions of CP/CPPS patients, is partially regulated by downstream activation of the HPA axis. Neonatal maternal separation (NMS) has been used for over two decades to study the outcomes of early life stress in rodent models, including changes in the HPA axis and visceral sensitivity. Here we provide a detailed protocol for using NMS as a preclinical model of CP/CPPS in male C57BL/6 mice. We describe the methodology for performing NMS, assessing perigenital mechanical allodynia, and histological evidence of mast cell activation. We also provide evidence that early psychological stress can have long-lasting effects on the male urogenital system in mice.

We are measuring perigenital mechanical sensitivity and mast cell activation in the prostate of male C57BL/6 mice that underwent an early life stress paradigm &#8211; neonatal maternal separation, in order to induce a preclinical model of chronic prostatitis/chronic pelvic pain syndrome.

Chronic prostatitis/chronic pelvic pain syndrome (CP/CPPS) has a lifetime prevalence of 14% and is the most common urological diagnosis for men under the ...

Methods for In Vivo Biomechanical Testing on Brachial Plexus in Neonatal Piglets

Neonatal brachial plexus palsy (NBPP) is a stretch injury that occurs during the birthing process in nerve complexes located in the neck and shoulder regions, collectively referred to as the brachial plexus (BP). Despite recent advances in obstetrical care, the problem of NBPP continues to be a global health burden with an incidence of 1.5 cases per 1,000 live births. More severe types of this injury can cause permanent paralysis of the arm from the shoulder down. Prevention and treatment of NBPP warrants an understanding of the biomechanical and physiological responses of newborn BP nerves when subjected to stretch. Current knowledge of the newborn BP is extrapolated from adult animal or cadaveric BP tissue instead of in vivo neonatal BP tissue. This study describes an in vivo mechanical testing device and procedure to conduct in vivo biomechanical testing in neonatal piglets. The device consists of a clamp, actuator, load cell, and camera system that apply and monitor in vivo strains and loads until failure. The camera system also allows monitoring of the failure location during rupture. Overall, the presented method allows for a detailed biomechanical characterization of neonatal BP when subjected to stretch.

Methods for In Vivo Biomechanical Testing on Brachial Plexus in Neonatal Piglets

Presented here are methods to perform in vivo biomechanical testing on brachial plexus in a neonatal piglet model.

Neonatal brachial plexus palsy (NBPP) is a stretch injury that occurs during the birthing process in nerve complexes located in the neck and shoulder ...

Biomechanical Testing of Murine Tendons

Tendon disorders are common, affect people of all ages, and are often debilitating. Standard treatments, such as anti-inflammatory drugs, rehabilitation, and surgical repair, often fail. In order to define tendon function and demonstrate efficacy of new treatments, the mechanical properties of tendons from animal models must be accurately determined. Murine animal models are now widely used to study tendon disorders and evaluate novel treatments for tendinopathies; however, determining the mechanical properties of mouse tendons has been challenging. In this study, a new system was developed for tendon mechanical testing that includes 3D-printed fixtures that exactly match the anatomies of the humerus and calcaneus to mechanically test supraspinatus tendons and Achilles tendons, respectively. These fixtures were developed using 3D reconstructions of native bone anatomy, solid modeling, and additive manufacturing. The new approach eliminated artifactual gripping failures (e.g., failure at the growth plate failure rather than in the tendon), decreased overall testing time, and increased reproducibility. Furthermore, this new method is readily adaptable for testing other murine tendons and tendons from other animals.

The protocol describes efficient and reproducible tensile biomechanical testing methods for murine tendons through the use of custom-fit 3D printed fixtures.

Tendon disorders are common, affect people of all ages, and are often debilitating. Standard treatments, such as anti-inflammatory drugs, rehabilitation, ...

Evaluating the Procedure for Performing Awake Cystometry in a Mouse Model

Awake filling cystometry has been used for a long time to evaluate bladder function in freely moving mice, however, the specific methods used, vary among laboratories. The goal of this study was to describe the microsurgical procedure used to implant an intravesical tube and the experimental technique for recording urinary bladder pressure in an awake, freely moving mouse. In addition, experimental data is presented to show how surgery, as well as tubing type and size, affect lower urinary tract function and recording sensitivity. The effect of tube diameter on pressure recording was assessed in both polyethylene and polyurethane tubing with different internal diameters. Subsequently, the best performing tube from both materials was surgically implanted into the dome of the urinary bladder of male C57BL/6 mice. Twelve-hour, overnight micturition frequency was recorded in healthy, intact animals and animals 2, 3, 5, and 7 days post-surgery. At harvest, bladders were assessed for signs of swelling using gross observation and were subsequently processed for pathological analysis. The greatest extent of bladder swelling was observed on day 2 and 3, which correlated with behavioral voiding data showing significantly impaired bladder function. By day 5, bladder histology and voiding frequency had normalized. Based on the literature and evidence provided by our studies, we propose the following steps for in vivo recording of intravesical pressure and voided volume in an awake mouse: 1) Perform the surgery using an operating microscope and microsurgical tools, 2) Use polyethylene-10 tubing to minimize movement artifacts, and 3) Perform cystometry on post-operative day 5, when bladder swelling resolves.

This study describes the surgical procedures and experimental techniques for performing awake cystometry in a freely moving mouse. In addition, it provides experimental evidence to support its optimization and standardization.

Awake filling cystometry has been used for a long time to evaluate bladder function in freely moving mice, however, the specific methods used, vary among ...

Ultrasonography in Experimental Reproductive Investigations on Rats

With the development of assisted reproductive technology and the ethical limitations of research on humans, rat animal models have been widely used in reproductive medicine. In the past, the study of reproductive system development in rodents has been based on one-time histological examination of excised tissues. Recently, with the development of high-resolution transabdominal ultrasound, high-quality sonography can now be performed to evaluate the reproductive organs of rats, allowing a new method for studying the reproductive system. Images were obtained using a high-resolution ultrasonographic system. Gynecological ultrasonography was performed on 28 eight-week-old non-pregnant rats and 5 pregnant Sprague-Dawley rats. We describe how to recognize organs of the reproductive system and associated structures in typical views during different phases of the estrus cycle. Color flow Doppler was used to measure uterine artery blood flow and evaluate uterine blood flow pattern changes during different stages of pregnancy. We have demonstrated that ultrasound exploration is a useful method for evaluating changes in internal reproductive organs. Its use raises the possibility of conducting additional experiments, including medical or surgical procedures, and provides the ability to monitor sonographic changes to internal organs without sacrificing animals.

This manuscript describes the utility of ultrasound performed on female rats to design experimental models for reproductive and gynecological investigation. A step-by-step explanation of how to perform ultrasonographic evaluation is shown.

With the development of assisted reproductive technology and the ethical limitations of research on humans, rat animal models have been widely used in ...

Assessing Murine Resistance Artery Function Using Pressure Myography

Pressure myograph systems are exquisitely useful in the functional assessment of small arteries, pressurized to a suitable transmural pressure. The near physiological condition achieved in pressure myography permits in-depth characterization of intrinsic responses to pharmacological and physiological stimuli, which can be extrapolated to the in vivo behavior of the vascular bed. Pressure myograph has several advantages over conventional wire myographs. For example, smaller resistance vessels can be studied at tightly controlled and physiologically relevant intraluminal pressures. Here, we study the ability of 3rd order mesenteric arteries (3-4 mm long), preconstricted with phenylephrine, to vaso-relax in response to acetylcholine. Mesenteric arteries are mounted on two cannulas connected to a pressurized and sealed system that is maintained at constant pressure of 60 mmHg. The lumen and outer diameter of the vessel are continuously recorded using a video camera, allowing real time quantification of the vasoconstriction and vasorelaxation in response to phenylephrine and acetylcholine, respectively.
	To demonstrate the applicability of pressure myography to study the etiology of cardiovascular disease, we assessed endothelium-dependent vascular function in a murine model of systemic hypertension. Mice deficient in the &alpha;1 subunit of soluble guanylate cyclase (sGC&alpha;1-/-) are hypertensive when on a 129S6 (S6) background (sGC&alpha;1-/-S6) but not when on a C57BL/6 (B6) background (sGC&alpha;1-/-B6). Using pressure myography, we demonstrate that sGC&alpha;1-deficiency results in impaired endothelium-dependent vasorelaxation. The vascular dysfunction is more pronounced in sGC&alpha;1-/-S6 than in sGC&alpha;1-/-B6 mice, likely contributing to the higher blood pressure in sGC&alpha;1-/-S6 than in sGC&alpha;1-/-B6 mice. 
	Pressure myography is a relatively simple, but sensitive and mechanistically useful technique that can be used to assess the effect of various stimuli on vascular contraction and relaxation, thereby augmenting our insight into the mechanisms underlying cardiovascular disease.

In pressure myography, an intact small segment of a vessel is mounted onto two small cannulas and pressurized to a suitable luminal pressure. Here, we describe the method to measure vasorelaxation response of the mouse 3rd order mesenteric arteries in c57 and sGC&alpha;1-/- mice using pressure myography.

Pressure myograph systems are  exquisitely useful in the functional assessment of small arteries, pressurized  to a suitable transmural pressure. The  ...

Biaxial Basal Tone and Passive Testing of the Murine Reproductive System Using a Pressure Myograph

Summary

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Measuring Left Ventricular Pressure in Late Embryonic and Neonatal Mice

Measurement of Tactile Allodynia in a Murine Model of Bacterial Prostatitis

Back Mechanical Sensitivity Assessment in the Rat for Mechanistic Investigation of Chronic Back Pain

Intrauterine Telemetry to Measure Mouse Contractile Pressure In Vivo

Assessment of Perigenital Sensitivity and Prostatic Mast Cell Activation in a Mouse Model of Neonatal Maternal Separation

Methods for In Vivo Biomechanical Testing on Brachial Plexus in Neonatal Piglets

Biomechanical Testing of Murine Tendons

Evaluating the Procedure for Performing Awake Cystometry in a Mouse Model

Ultrasonography in Experimental Reproductive Investigations on Rats

Assessing Murine Resistance Artery Function Using Pressure Myography