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Are the precapillary sphincters and metarterioles universal components of the microcirculation? An historical review

The Journal of Physiological Sciences volume 63pages 319–331 (2013)Cite this article

Abstract

The microcirculation is a major topic in current physiology textbooks and is frequently explained with schematics including the precapillary sphincters and metarterioles. We re-evaluated the validity and applicability of the concepts precapillary sphincters and metarterioles by reviewing the historical context in which they were developed in physiology textbooks. The studies by Zweifach up until the 1950s revealed the unique features of the mesenteric microcirculation, illustrated with impressive schematics of the microcirculation with metarterioles and precapillary sphincters. Fulton, Guyton and other authors introduced or mimicked these schematics in their physiology textbooks as representative of the microcirculation in general. However, morphological and physiological studies have revealed that the microcirculation in the other organs and tissues contains no metarterioles or precapillary sphincters. The metarterioles and precapillary sphincters were not universal components of the microcirculation in general, but unique features of the mesenteric microcirculation.

Introduction

The microcirculation is one of the major topics in the study of physiology and histology. In current physiology textbooks, the general architecture of the microcirculation is frequently explained with schematic drawings depicting precapillary sphincters and metarterioles in addition to arterioles, capillaries and venules. Judging from the main text and figures with legends in relatively recent textbooks such as Johnson’s [1] (Fig. 1) and Boron and Boulpaep’s [2] (Fig. 2), one could assume that the precapillary sphincters and metarterioles are universal components of the microcirculation in various tissues and organs of the human body.

Fig. 1
figure 1

Schematic diagram of the microcirculation. From Johnson [1]

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Fig. 2
figure 2

Idealized microcirculatory circuit. From Boron and Boulpaep [2]

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Since the concept of precapillary sphincters and metarterioles is quite popular in physiology textbooks, one might expect that previous physiological investigations had revealed the existence of these structures in various tissues with reasonable certainty. Nevertheless, the existence of precapillary sphincters as universal components of the microcirculation has been questioned by some physiologists. McCuskey [3] pointed out the diversity of the structure and function of the microcirculation among various tissues and criticized the harsh generalization of precapillary sphincters. Wiedeman et al. [4] recommended the expression “precapillary resistance” instead of precapillary sphincters based on the absence of consensus on the definition of the precapillary sphincter and of supportive morphological findings. Furthermore, in the literature surveyed using PubMed, the metarterioles were frequently conceived in a restricted sense as representing the smallest and last order of arterioles instead of in their original sense of thoroughfare channels connecting arterioles and venules.

In the present article, we re-evaluated the validity and applicability of the concept of precapillary sphincters and metarterioles by reviewing the historical context in which these concepts were developed and accepted in four steps. In the first part, we investigated the historical process of how the schematics of these concepts was developed and incorporated into physiology textbooks. In the second part, we evaluated the validity of the concepts by examining the physiological literature on the microcirculation of the mesentery in which the concepts were originally proposed. In the third part, we examined the applicability of the concepts to the microcirculation of organs other than the mesentery. In the fourth part, we verified the structural counterparts of the concepts by examining the histological literature on the vasculature.

The origin of the schematics of the microcirculation

We examined the available physiology textbooks from Haller’s “Primae Lineae Physiologiae” of 1747 [5] to the most modern “Medical Physiology” by Boron and Boulpaep [2] as well as histology textbooks from Kölliker’s “Handbuch der Gewebelehre des Menschen” of 1852 [6] to Ross and Pawlina’s “Histology” [7] to look for accounts and schematics of the microcirculation. The earliest example of a textbook containing an account and schematics of the microcirculation was “Howell’s Textbook of Physiology,” 15th edition, edited by Fulton [8], in which the schematics was reproduced from figure 1 of Zweifach’s 1937 article [9] on the mesentery of the frog without either precapillary sphincters or metarterioles. Fulton’s “A Textbook of Physiology,” 17th edition, published in 1955 [10], contained a new schematic of the ideal capillary bed containing both precapillary sphincters and metarterioles reproduced from figure 1 of Zweifach et al.'s 1953 publication [11]. Thereafter, the physiology textbooks usually contain an account of the microcirculation together with schematics showing both precapillary sphincters and metarterioles, as shown in Table 1. Recent histology textbooks, such as Ross and Reith’s histology published in 1985 [12] and its later versions, contain an account and schematics of the microcirculation.

Table 1 Features of the schematics of the microcirculation in the physiology textbooks
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The schematics of the microcirculation in the textbooks shown in Table 1 were either reproduced from a few of Zweifach’s articles or drawn without any indication of the source. We found that six different schematics from four of Zweifach’s articles were used as the source in the textbooks.

Among the six schematics, two figures contained neither precapillary sphincters nor metarterioles, including figure 1 from Zweifach’s 1937 article [9] on the frog mesentery (Fig. 3) and figure 4 from Zweifach’s 1950 article [13] on the dog mesentery (Fig. 4). Strangely, both figures were identical except that the latter was rotated upside-down. The former was reproduced in Fulton’s physiology in 1946 [8] and 1949 [14], and the latter was reproduced in Bard’s physiology in 1961 [15] and its later versions until Mountcastle’s physiology in 1980 [16].

Fig. 3
figure 3

Camera lucida outline of vessels in the capillary bed of the frog mesentery. Figure 1 from Zweifach [9]

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Fig. 4
figure 4

Camera lucida drawing of the capillary bed in mesentery of dog. Figure 4 from Zweifach [13]

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One of the six figures showed sketches of observations of the mesentery microcirculation with precapillary sphincters and metarterioles, namely figure 1 in Zweifach’s 1950 article [13] (Fig. 5). This figure was reproduced in Bard’s physiology in 1961 [15] and its later versions up until Mountcastle’s physiology in 1980 [16].

Fig. 5
figure 5

Camera lucida drawing of the capillary bed in the mesentery of the cat. Figure 1 from Zweifach [13]

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The other three figures represented an idealized microcirculation and contained both precapillary sphincters and metarterioles, including figure 1 of Chambers and Zweifach’s article from 1944 [17] (Fig. 6), figure 2 of Zweifach’s article from 1950 [13] (Fig. 7) and figure 1 of Zweifach et al. from 1953 [11] (Fig. 8). The first one was reproduced in Guyton’s 1956 physiology book [18], the second in Guyton’s 1961 physiology book [19] and its later versions, and the third in Fulton’s 1955 physiology book [10] and Ross and Reith’s 1985 histology [12] and its later versions.

Fig. 6
figure 6

Diagram of a functional unit of the capillary bed. Figure 1 from Chambers and Zweifach [17]

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Fig. 7
figure 7

A schematic representation of the structural pattern of the capillary bed. Figure 2 from Zweifach [13]

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Fig. 8
figure 8

Diagrammatic representation of basic structural pattern of the terminal vascular bed as visualized in the mesentery. Figure 1 from Zweifach et al. [11]

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The other schematics of the microcirculation in the physiology textbooks did not use Zweifach’s article as the source for the figures and appeared to be original drawnings. The schematic in Berne and Levy’s physiology in 1967 [20] and its later versions (Fig. 9) showing both precapillary sphincters and metarterioles was credited as being taken from Zweifach of unknown origin, but it may have been an original drawing since no similar figures are found in Zweifach’s literature, and the same schematic was used in Berne and Levy’s physiology textbook in 1986 [21] and its later versions without any reference to the source. The schematics in Johnson’s 1992 book on physiology [22] and its later versions (Fig. 1) and Boron and Boulpaep’s book on physiology in 2003 [23] and the second edition (Fig. 2) with both precapillary sphincters and metarterioles were newly drawn without any particular source indicated.

Fig. 9
figure 9

Schematic drawing of the microcirculation (after Zweifach). From Berne and Lavy [20]

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The above survey indicated that the schematics of the microcirculation in the current textbooks of physiology relied on specific articles by Zweifach before 1953. In the following part, we will examine the literature on physiological research on the microcirculation, especially those by Zweifach, to evaluate the extent of applicability of the concepts of precapillary sphincters and metarterioles.

Physiological research as the basis of precapillary sphincters and metarterioles

A series of investigations by Zweifach utilized the mesentery of a few different animals for visualization of the microcirculation in vivo, beginning with Zweifach’s research in 1937 [9] on the frog mesentery. In this article Zweifach observed the microcirculation in both living and fixed material and found neither precapillary sphincters nor metarterioles, as shown in the camera lucida outline of the capillary bed (Fig. 3). Two years later, in 1939, Zweifach [24] reported the first indication of precapillary sphincters in the rabbit and mouse mesentery by describing a valve-like fold comprised of endothelium at the point where a capillary branch leaves an arteriole. He stated that the folds behaved like an endothelial sphincter when the parent trunk contracted, but further stated that in arterioles, closure was aided by muscle cells at the point of capillary exit. In 1942 Chambers and Zweifach [25] presented a motion picture that showed “sphincter like functioning of the precapillaries at their junctions with the arteriole.” In 1944, Chambers and Zweifach [17] presented a diagram of a functional unit of the capillary bed in which thoroughfare vessels with preferentially rapid blood flow were designated as metarterioles and a specific area at the origin of capillaries as precapillary sphincters, as shown in a diagram of the functional unit of capillary bed (Fig. 6).

In introducing the new concepts of metarterioles and precapillary sphincters, Chambers and Zweifach [17] referred to previous investigations to support their conclusions. They claimed that the two different vascular components observed by Sandison [26] and by Clark and Clark [27] in the rabbit ear either with or without contractile activity corresponded to the metarterioles and capillaries in the mesentery. However, the vascular components with contractile activity in the rabbit ear were different from metarterioles, since the metarterioles as proposed by Chambers and Zweifach [17] represented thoroughfare channels connecting arterioles and venules. Chambers and Zweifach [17] claimed that the contractile mechanism observed at the arteriolar source of the capillaries in three previous studies, including Richards and Schmidt’s [28] research on the glomerular capillaries of the frog, Crawford’s [29] research on the epidermal papillae at the base of the human finger, and Fulton and Lutz’s [30] study on frog retrolingual membrane, was so variable and ambiguous that the specific vasoconstriction at the origin of the capillaries could not be determined and that the last one described the precapillary contractility.

Summarizing the above literature survey, it must be concluded that the precapillary sphincters and metarterioles identified by several studies by Zweifachs provide enough evidence on the mesentery microcirculation, but their findings cannot be accepted as evidence for the microcirculation of the various tissues and organs in general.

Zweifach provided four types of schematics including precapillary sphincters and metarterioles in three articles. The first type was in an article on the mammalian omentum and mesentery by Chambers and Zweifach in 1944 [17] presenting a diagram of the functional unit of the capillary bed (Fig. 6), while the second and third types were published in a conference report by Zweifach in 1950 [13] either as a camera lucida drawing of the capillary bed in the mesentery of a cat or as a schematic representation of the structural pattern of the capillary bed (Figs. 5, 7). The fourth type was described by Zweifach et al. in 1953 [11] in an article on the influence of the adrenal cortex on the microcirculation as a diagrammatic representation of the basic structural pattern of the terminal vascular bed as visualized in the mesentery (Fig. 8). Zweifach clearly recognized that evidence on the precapillary sphincters and metarterioles was only available in the mesentery, but obviously wanted to present them as universal elements of the microcirculation.

However, the metarterioles and precapillary sphincters were topics of later physiological research on the microcirculation of various tissues and organs including the skeletal muscles [3139], skin [40, 41], subcutaneous adipose tissue [42], gastric mucosa [43], liver [44] and heart [45]. In these studies the metarterioles and precapillary sphincters obviously differed from the original concepts by Zweifach. In these studies, the metarterioles were conceived in a restricted sense as representing the smallest and last order of arterioles [41, 45], and they were fundamentally different from the thoroughfare channels connecting arterioles and venules as originally proposed by Zweifach [11, 13, 17] and accepted in modern physiology textbooks [1, 2, 10, 15, 16, 1823]. Furthermore, in these studies the precapillary sphincters were not substantially demonstrated at specific portions of the microcirculation, but the change in vascular resistance was interpreted as effected by “precapillary sphincter tone” or “precapillary sphincter activity” [3439, 43], or the last segments of the arterial tree before capillaries were merely designated as the precapillary sphincters without showing any specific localization of smooth muscle cells [3133, 40, 42, 44]. As Wiedeman et al. [4] recommended, the expression of “precapillary resistance” instead of precapillary sphincters may be preferable when structural evidence is not available. It would be appropriate to conclude that the concepts of precapillary sphincters and metarterioles are diverse mainly because of the difference in definitions adopted by recent physiological researchers from those originally proposed by Zweifach and accepted in the current physiology textbooks. In addition, the difference in definitions was blurred by the structural and functional heterogeneity of the microcirculation among tissues and organs, as will be discussed in the next section.

The architecture of the microcirculation is diverse and specific to organs

After the pioneering studies of Zweifach and coworkers, the structure and function of the microcirculation were studied in other organs such as the skeletal muscle, skin, heart, liver, kidney, intestine, etc. The microcirculation architecture was revealed to be quite diverse among organs and had specific patterns suitable to the functional demands of the individual organs.

In skeletal muscle, the arterioles and venules branch successively to become the terminal segments that supply and drain microvascular units, respectively [46]. The terminal segments of arterioles give rise to a group of capillaries to form a microvascular unit, with respective capillaries converging on collecting venules. Between the arterioles and venules, there are no preferential channels representing the metarterioles. The total flow into a muscle is governed by the whole arterial tree from the feeding arteries to the terminal arteries. The specific precapillary sphincters at the junction of arterioles are not present in the microcirculation of skeletal muscles. The microcirculation in the skeletal muscle is arranged to distribute the blood flow evenly to the individual muscle fibers and to modulate the blood flow to meet the increased demand during exercise.

In the skin, the microcirculation is organized as two horizontal plexuses [47]. One is situated 1–1.5 mm below the skin surface, and the other is at the dermal-subcutaneous junction. Ascending arterioles and descending venules are paired as they connect the two plexuses. The lower plexus is formed by perforating vessels from the underlying muscles and subcutaneous fat, and it supplies the hair bulbs and sweat glands. The superficial horizontal plexus supplies capillaries that course close to the dermal-epidermal junction and also serve as a thermal radiator.

In the coronary microcirculation, the small penetrating arteries give rise to arterioles at almost right angles, which take either longitudinal or oblique courses to the muscle fibers to give off capillaries around the muscle fibers [48]. Between the arterioles and venules, there are no preferential channels representing the metarterioles. The coronary resistance is considered to be primarily regulated by arterioles with diameters of 50–200 μm, which are most responsible for metabolic, myogenic and humoral stimuli [49]. The coronary microcirculation is arranged to distribute the blood flow evenly to the cardiac muscle cells and to modulate the blood flow to meet the increased demand for high cardiac output.

In the liver, the hepatic arteries (HAs) and portal veins (PVs) divide successively into terminal HAs and PVs in the connective tissue stroma at the periphery of the hepatic lobules. The terminal PVs directly supply the sinusoids, while the terminal HAs drains into the terminal PVs and the proximal part of the sinusoids. The sinusoidal blood is drained via central venules into the hepatic veins [50]. There are neither metarterioles nor precapillary sphincters in the liver. The hepatic microcirculation is thought to be suitable for handling nutrients absorbed in the intestine with the hepatocytes around the sinusoids.

In the kidney, the arteries enter the parenchyme and divide into the arcuate arteries at the corticomedullary boundary from which the interlobular arteries arise toward the cortical surface to branch off successively into the afferent arterioles to supply the glomerular capillaries in the individual glomeruli [51]. The efferent arterioles drain the individual glomeruli to pour into the peritubular capillaries, which drain into branches of the renal veins. There are neither metarterioles nor precapillary sphincters in the kidney. The renal microcirculation is thought to be suitable for large amounts of glomerular filtration together with reabsorption of most of the fluids in the renal tubule.

In the small intestine, the arterial and venous plexuses are formed in the submucosa [52]. From the submucosal arterial plexus, a single arteriole arises to supply the intestinal villus to reach the tip of the villus and breaks up into a fountain-like pattern of capillaries. These capillaries drain into the villus venules, which pass straight down to enter the submucosal venous plexus. There are neither metarterioles nor precapillary sphincters in the intestinal wall. The intestinal microcirculation is thought to be suitable for reabsorption of fluids and nutrients in the intestinal villi.

However, in the mesenteric microcirculation, the metarterioles have been recognized by the other authors as shunting arterioles [53]. The blood flow through the arteriovenous shunt is reported to be 2 or 3 % of the total mesenteric blood flow [54, 55].

The metarterioles in the mesentery represent thoroughfare channels between the arterioles and venules and therefore can be regarded as a kind of arteriovenous anastomosis. These have been reported in various tissues and organs including the skin, skeleton, muscle, lung, heart, intestinal canal, kidney, brain, eye and ear [56]. However, a systematic survey in various organs reported that substantial arteriovenous anastomoses are present only in the ears and skin and absent in the brain, heart, kidneys, skeletal muscles, stomach, small and large intestines, spleen, adrenal glands, liver, bones, fat and salivary glands [57]. In the skin, arteriovenous anastomoses are known to have specific physiological functions to prevent lowering of the body temperature [47, 58]. In pathological conditions, arteriovenous anastomoses in the gastric mucosa can cause local ischemia and prevent bleeding from a gastric ulcer [59]. The metarterioles in the mesentery are structurally and functionally clearly distinguished from the representative arteriovenous anastomoses in the skin.

Morphological observations on the microvasculature

The structure of the microvasculature has been repeatedly investigated in various tissues by means of three electron microscopy methods. By transmission electron microscopy (TEM), the smooth muscle cells and extracellular matrices of the vascular wall can be well visualized and analyzed, but it is usually difficult to identify the observed location within the three-dimensional branching of the vascular tree on the sectional planes. Thus, identification of precapillary sphincters may only be possible after repeated careful observations of the microvasculature with TEM. By scanning electron microscopy of vascular casts (SEM-vc), the three-dimensional branching pattern of the vasculature can be well visualized and analyzed, but it was practically impossible to identify the cellular composition of the vascular wall. The precapillary sphincter can be inferred by constriction of the vascular casts at the base of the vascular branches with SEM-vc. By scanning electron microscopy after removal of the extracellular matrices (SEM-rem), both the structure of the vascular wall and the three-dimensional branching pattern can be well visualized, but the cellular types can be identified only tentatively on the basis of cellular shape. The precapillary sphincters can be identified convincingly with SEM-rem.

In a search of the literature, we found 36 morphological studies on the microvasculature in 16 kinds of tissues employing one of the three morphological methods (Table 2). Six of the studies described precapillary sphincters, two employing TEM [60, 61] and four employing SEM-vc [6266]. In the other studies, the existence of precapillary sphincters was neither mentioned in the text nor demonstrated in the figures; in some studies their absence was concluded. To evaluate the existence of precapillary sphincters, we scrutinized the descriptions and figures of the six studies reporting precapillary sphincters.

Table 2 Morphological studies on the microvasculature in various tissues and organs with three different methods
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Rhodin made detailed observations of the microvasculature employing TEM [60]. The identification of the observation site was accurate enough, since he selected the observation site in the whole-mount specimens of the muscular fascia. He identified the precapillary sphincter at the angle of small vessel branching, but the figures showed smooth muscle cells present not only at the angle but also in the walls of both the trunk vessels and the branches. The precapillary sphincters reported by Rhodin [60] were not separate smooth muscle cells at the angle of vascular branching, but a part of the continuous smooth muscle layer at the angle, so that they did not deserve the name precapillary sphincters.

Precapillary sphincters were reported in the microvasculature of the heart with TEM and SEM-vc. Sherf et al. [61] described precapillary sphincters with TEM in the human heart, but the electron micrographs did not allow determination of the location of smooth muscle cells in the three-dimensional vascular tree, so that the identification of precapillary sphincters was groundless and doubtful. Anderson and Anderson reported an indication of precapillary sphincters in dog heart with SEM-vc [63], but the abrupt interruption and irregular shape of the vascular casts indicated that the resin did not sufficiently fill the vascular lumina so that the identification of precapillary sphincters was not based on sound evidence. He et al. [66] reported step-wise constriction of arterioles in yaks and interpreted this as the precapillary sphincters being distributed in a certain section of the arterioles. These structures were far from the precapillary sphincters branching into capillaries reported in the physiological studies. The precapillary sphincters were not mentioned in the other studies on the microvasculature of the heart, including Tsunenari’s [67] research with TEM and Higuchi et al.’s [68] study with SEM-rem.

Precapillary sphincters were reported in the microvasculature of the brain with SEM-vc by Nakai et al. [64] and Castenholz [65]. Observations with SEM-vc did not provide conclusive evidence of precapillary sphincters, as mentioned above. However, Shiraishi et al. [69] did not mention the precapillary sphincters, and Ushiwata and Ushiki [70] denied the existence of precapillary sphincters in the brain microvasculature with the more reliable method of SEM-rem.

As shown above, the morphological evidence did not verify the existence of precapillary sphincters in the microvasculature of the muscular fascia, heart and brain. In the other 13 kinds of tissues, the precapillary sphincters were not observed at all with TEM, SEM-vc or SEM-rem. Our own observations of the microvasculature in the lung [71], kidney [7274] and intestine [75, 76] did not show any indication of precapillary sphincters.

The arterioles received an abundance of aminergic (adrenergic) innervation in many organs such as the skeletal muscles [7780], salivary glands [81], nasal mucosa [82], gastric and intestinal mucosa [83, 84], and brain [85]. Histochemical studies of adrenergic nerves in these organs can provide a good indication of smooth muscles in the walls of arteries and arterioles, but did not show the existence of precapillary sphincters [77, 78, 8085]. On the whole, we should conclude that no morphological evidence has been obtained to support the existence of precapillary sphincters in all the tissues so far investigated.

Conclusion

The studies by Zweifach up until the 1950s revealed the unique features of the mesenteric microcirculation and provided impressive schematics of the microcirculation with metarterioles and precapillary sphincters. Fulton, Guyton and other authors introduced or mimicked these schematics in their physiology textbooks as representative of the microcirculation in general. However, morphological studies have revealed that the microcirculation in other organs and tissues contains no metarterioles or precapillary sphincters, and physiological studies on the microcirculation have used the terms metarterioles and precapillary sphincters differently. This reveals that the metarterioles and precapillary sphincters are not universal components of the microcirculation in general, but unique features of the mesenteric microcirculation. Therefore, explanations and illustrations of the microcirculation with metarterioles and precapillary sphincters can be regarded as inappropriate and misleading in physiology textbooks about the organs and tissues that aim to teach in general and not specific terms.

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Authors and Affiliations

  1. Department of Anatomy and Life Structure, Faculty of Medicine, Juntendo University, 2-1-1 Hongo, Bunkyo-ku, Tokyo, 113-8421, Japan

    Tatsuo Sakai & Yasue Hosoyamada

  2. Department of Nutrition, Faculty of Health Care Sciences, Chiba Prefectural University of Health Sciences, 2-10-1 Wakaba, Mihama-ku, Chiba-shi, Chiba, 261-0014, Japan

    Yasue Hosoyamada

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  1. Tatsuo Sakai
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Correspondence to Tatsuo Sakai.

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Sakai, T., Hosoyamada, Y. Are the precapillary sphincters and metarterioles universal components of the microcirculation? An historical review. J Physiol Sci 63, 319–331 (2013). https://doi.org/10.1007/s12576-013-0274-7

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The Journal of Physiological Sciences

ISSN: 1880-6562

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