Summary
Smooth muscles of viscera undergo a large increase in volume when there is a chronic, partial obstruction impairing the flow of lumenal contents. Hypertrophy of smooth muscle occurs in various medical conditions and several methods are available for inducing it experimentally in laboratory animals, especially in urinary bladder, small intestine and ureter. The hypertrophic response differs somewhat with the type of organ, the animal species, the age of the subject, and the experimental procedure.
Ten- to fifteen-fold increases in muscle volume develop within a few weeks in the urinary bladder or the ileum of adult animals, a growth that would not have occurred in the lifespan of the animal without the experimental intervention. The general architecture of the muscle and the boundaries with adjacent tissues are well preserved. In intestinal hypertrophy, muscle cells increase in number: mitoses are found in mature, fully differentiated muscle cells. Cell division by full longitudinal splitting of muscle cells may also occur.
Enlargement of muscle cells accounts for most of the muscle hypertrophy. The hypertrophic muscle cell has an irregular profile with deep indentations of the cell membrane, bearing caveolae and dense bands; however, the cell surface grows less than the cell volume (reduction of surface-to-volume ratio). The nucleus is crenated and is much less enlarged than the cell (reduction of the nucleo-plasmatic ratio). Mitochondria grow in number but in some muscles their spatial density decreases; intermediate filaments increase more than myofilaments. The spatial density of sarcoplasmic reticulum is generally increased. In the hypertrophic intestine, gap junctions increase in number and size; in the bladder, gap junctions are absent both in control and in hypertrophy. Thus the hypertrophic muscle cell is not only larger than a control cell, but has a different pattern of its structural components.
Extensive neo-angiogenesis maintains a good blood supply to the hypertrophic muscle. The density of innervation is much decreased in the hypertrophic intestine, whereas it appears well maintained in the bladder. Neuronal enlargement is found in the intramural ganglia of the intestine and in the pelvic ganglion.
The mechanisms involved in hypertrophic growth are unknown. Three possible factors, mechanical factors, especially stretch, altered nerve discharge, and trophic factors are discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Addis T (1932) Hypertrophy of the gastro-intestinal tract and high residue diets. Am J Physiol 99:417–423
Andersen JT (1976) Detrusor hyperreflexia in benign infravesical obstruction. A cystometric study. J Urol 115:532–534
Anversa P, Vitali-Mazza L, Visiolo O, Marchetti G (1971) Experimental cardiac hypertrophy. Quantitative ultrastructural study in the compensatory stage. J Mol Cell Cardiol 3:213–227
Barnes MJ, Morton LF, Levene CI (1976) Synthesis of collagen types I and III by pig medial smooth muscle cells in culture. Biochem Biophys Res Commun 70:339–347
Booth CC, Evans KT, Menzies T, Street DF (1958/59) Intestinal hypertrophy following partial resection of the small bowel in the rat. Br J Surg 46:403–410
Bortoff A, Sillin LF (1986) Changes in intercellular electrical coupling of smooth muscle accompanying atrophy and hypertrophy. Am J Physiol 250: C292-C298
Brent L (1973) The response of smooth muscle cells in the rabbit colon to anal stenosis: a preliminary report. Pathology 5:209–218
Brent L, Stephens FD (1975) The response of smooth muscle cells in the rabbit urinary bladder to outflow obstruction. Invest Urol 12:494–502
Brown RC, Kelleher J, Losowsky MS (1979) The effect of pectin on the structure and function of the rat small intestine. Br J Nutr 42:357–365
Bülbring E (1955) Correlation between membrane potential, spike discharge and tension in smooth muscle. J Physiol (Lond) 128:200–221
Burke JM, Ross R (1977) Collagen synthesis by monkey arterial smooth muscle cells during proliferation and quiescence in culture. Exp Cell Res 107:387–395
Carey EJ (1921) Studies in the dynamics of histogenesis. VII. The experimental transformation of the smooth bladder muscle of the dog, histologically into cross-striated muscle and physiologically into an organ manifesting rhythmicality. Am J Anat 29:341–362
Carpenter FG, Root WS (1951) Effect of parasympathetic denervation on feline bladder function. Am J Physiol 166:686–691
Cervero F, Sann H (1989) Mechanically evoked responses of afferent fibres innervating the guinea-pig's ureter: an in vitro study. J Physiol (Lond) 412:245–266
Chamley-Campbell J, Campbell GR, Ross R (1979) The smooth muscle cell in culture. Physiol Rev 59:1–61
Christensen O (1987) Mediation of cell volume regulation by Ca2+ influx through stretch-activated channels. Nature 330:66–68
Coelho JCU, Gouma DJ, Moody FG, Li YF, Senninger N (1986) Gastrointestinal motility following small bowel obstruction in the opossum. J Surgical Res 41:274–278
Cortivo R, Pagano F, Passerini G, Abatangelo G, Castellani I (1981) Elastin and collagen in the normal and obstructed bladder. Br J Urol 53:134–137
Csapo A, Erdos T, De Mattos CR, Gramss E, Moscowitz C (1965) Stretch-induced uterine growth, protein synthesis and function. Nature 207:1378–1379
Cullen BM, Harkness RD (1968) Collagen formation and changes in cell population in the rat uterus after distension with wax. Q J Exp Physiol 53:33–42
Cussen LJ, Tymms A (1972) Hyperplasia of ureteral muscle in response to acute obstruction of the ureter. Invest Urol 9:504–508
Elbadawi A, Meyer S, Malkowicz SB, Wein AJ, Levin RM, Atta MA (1989) Effects of short-term partial bladder outlet obstruction on the rabbit detrusor. An ultrastructural study. Neurourol Urodynam 8:89–116
Elliott TR (1907) The innervation of the bladder and urethra. J Physiol (Lond) 35:367–445
Falk IL (1960) Cecal enlargement in germfree animals. Nutr Rev 18:313–314
Fell BF, Smith KA, Campbell RM (1963) Hypertrophic and hyperplastic changes in the alimentary canal of the lactating rat. J Pathol Bacteriol 85:179–188
Filogamo G, Vigliani F (1954) Ricerche sperimentali sulla correlazione tra estensione del territorio di innervazione e grandezza delle cellule gangliari del plesso mienterico (di Auerbach), nel cane. Riv Patol Nerv Ment 75:441–462
Flint JM (1912) The effect of extensive resections of the small intestine. Bull Johns Hopkins Hosp 23:127–144
Gabella G (1979a) Hypertrophic smooth muscle. I. Size and shape of cells, occurrence of mitoses. II. Sarcoplasmic reticulum, caveolae and mitochondria. Cell Tissue Res 201:63–92
Gabella G (1979b) Hypertrophic smooth muscle. III. Increase in the number and size of gap junctions. IV. Myofilaments, intermediate filaments and some mechanical properties. Cell Tissue Res 201:263–288
Gabella G (1984a) Hypertrophic smooth muscle. V. Collagen and other extracellular materials. Vascularization. Cell Tissue Res 235:275–283
Gabella G (1984b) Size of neurons and glial cells in the intramural ganglia of the hypertrophic intestine of the guinea-pig. J Neurocytol 13:73–84
Gabella G (1987) Muscle hypertrophy in the partially obstructed intestine. In: Seidel CL, Weisbrodt NW (eds) Hypertrophic response in smooth muscle. CRC Press, Boca Raton, Fla, pp 45–76
Gabella G, Uvelius B (1990) Urinary bladder fine structure: normal and hypertrophic musculature. Cell Tissue Res 262:67–79
Gee WF, Kiviat MD (1975) Ureteral response to partial obstruction. Invest Urol 12:309–316
Gibson J, Laurent GJ, McAnulty RJ (1985) Collagen metabolism during muscle growth in the chicken: evidence for increased collagen deposition associated with a decreased degradation of newly synthesized collagen as well as an increased synthesis rate. J Physiol (Lond) 364:80P
Gillenwater JY, Morris SA, Bryan PR, Attinger F, Smith HC, McManamy JL (1978) In vivo smooth muscle function in normal and obstructed rabbit vas deferens. Invest Urol 16:207–212
Goldspink G (1971) Morphological adaptation due to growth and activity. In: Briskey EJ, Cassens RG, Marsh BB (eds) The physiology and biochemistry of muscle as a food. 2. University of Wisconsin Press, Madison, pp 521–536
Gordon HA (1959) Morphological and physiological characterization of germfree life. Ann NY Acad Sci 78:208–220
Gosling JA, Dixon JS (1980) Structure of trabeculated detrusor smooth muscle in cases of prostatic hypertrophy. Urol Int 35:351–355
Gosling JA, Gilpin SA, Dixon JS. Gilpin CJ (1986) Decrease in the autonomic innervation of human detrusor muscle in out-flow obstruction. J Urol 136:501–504
Goss RJ (1964) Adaptive Growth. Logos Press, London
Goss RJ, Liang MD, Weisholtz SJ, Peltzer TJ (1973) The physiological basis of urinary bladder hypertrophy. Proc Soc Exp Biol Med 142:1332–1335
Harkness MLR, Harkness RD (1954) The collagen content of the reproductive tract of the rat during pregnancy and lactation. J Physiol (Lond) 123:492–500
Harkness MLR, Harkness RD (1956) The distribution of the growth of collagen in the uterus of the pregnant rat. J Physiol (Lond) 132:492–501
Haussman M, Biancani P, Weiss RM (1979) Obstruction-induced changes in longitudinal force-length relations of rabbit ureter. Invest Urol 17:223–226
Heijden FL v d, James J (1975) Polyploidy in the human myometrium. Z Mikrosk Anat Forsch 89:18–26
Herczel E (1886) Experimentelle und histologische Untersuchungen über compensatorische Muskelhypertrophie bei Darmstenosen. Z Klin Med 11:321–341
Hoppeler H, Lüthi P, Claassen H, Weibel ER, Howald H (1973) The ultrastructure of normal human skeletal muscle. A morphometric analysis of untrained men, women and well trained orienteers. Pflügers Arch 344:217–232
Iacovou JW, Shorrock K, Birmingham AT, Bates CP (1989) Connective tissue infiltration of the obstructed bladder: the relationship to in vivo and in vitro function in chronic retention (abstract). Neurourol Urodyn 8:398–399
Jacobs LR (1985) Differential effects of dietary fibers on rat intestinal circular muscle cell size. Digest Dis Sci 30:247–252
Johansson B (1976) Structural and functional changes in rat portal veins after experimental portal hypertension. Acta Physiol Scand 98:381–383
Johansson B, Somlyo AP (1980) Electrophysiology and excitationcontraction coupling. In: Bohr DF, Somlyo AF, Sparks H Jr (eds) Handbook of physiology, section 2, The cardiovascular system, vol 2. Williams and Wilkins, Baltimore, pp 301–324
Kahn P, Graf T (1986) Oncogenes and Growth Control. Springer, Berlin
Ladányi P, Lelkes Gy (1968) Study of experimental fibrillogenesis in tunica muscularis of the rat ureter. Acta Morphol Acad Sci Hung 16:147–156
Lane PW (1966) Association of megacolon with two recessive spotting genes in the mouse. J Hered 57:29–31
Lange KH (1940) Über die Hypertrophie der glatten Muskulatur. Morphol Jahrb 84:363–402
Layman DL, Titus JL (1975) Synthesis of type I collagen by human smooth muscle cells in vitro. Lab Invest 33:103–107
Leung DYM, Glagov S, Mathews MB (1976) Cyclic stretching stimulates synthesis of matrix components by arterial smooth muscle cell in vitro. Science 191:475–477
Levin RM, High J, Wein AJ (1984) The effect of short-term obstruction on urinary bladder function in the rabbit. J Urol 132:699–701
Malmgren A, Sjögren C, Uvelius B, Mattiasson A, Andersson KE, Andersson PO (1987) Cystometrical evaluation of bladder instability in rats with infravesical outflow obstruction. J Urol 137:1291–1296
Mattiasson A, Uvelius B (1982) Changes in contractile properties in hypertrophic urinary bladder. J Urol 128:1340–1342
Mockless I, Hassouna MM, Kirulut GH, Seemeyer TA, Homsy YL, Coolsaet BLRA, Elhilali MM (1988) The evolution of artificial sphincter cuff in growing animals. J Urol 140:632–636
Nemeth PR, Kwee DJ, Weisbrodt NW (1983) Adaptation of intestinal muscle in bypassed loops after jejunoileal bypass in rat. Am J Physiol 244:G599-G603
Nissen R, Cardinale GJ, Udenfriend S (1978) Increased turnover of arterial collagen in hypertensive rats. Proc Nat Acad Sci USA 75:451–453
Nygaard K (1967) Resection of the small intestine in rats. Acta Chir Scand 133:233–248
Olesen S-P, Clapham DE, Davies PF (1988) Haemodynamic shear stress activates a K+ current in vascular endothelial cells. Nature 331:168–170
Owens GK, Schwartz SM (1983) Vascular smooth muscle cell hypertrophy and hyperploidy in the Goldblatt hypertensive rat. Circ Res 53:491–501
Page E, Polimeni PI, Zak R, Earley J, Johnson M (1972) Myofibrillar mass in rat and rabbit heart muscle. Correlation of microchemical and stereological measurements in normal and hypertrophic hearts. Circ Res 30:430–439
Peterson CM, Goss RJ, Atryzek V (1974) Hypertrophy of the rat urinary bladder following reduction of its functional volume. J Exp Zool 187:121–126
Philipson BM, Leth R, Kock NG (1985) Hypertrophy of ileal smooth muscle after construction of ileal reservoir in the rat. Virchows Arch [A] 406:417–424
Phillips BP, Wolfe PA, Gordon HA (1959) Studies on rearing the guinea pig germfree. Ann NY Acad Sci 78:183–207
Pillion DJ, Jenkins RL, Atchison JA, Stockard CR, Clements RS Jr, Crizzle WE (1988) Paradoxical organ-specific adaptations to streptozotocin diabetes mellitus in adult rats. Am J Physiol 254:E749-E755
Ross R, Klebanoff SJ (1971) The smooth muscle cell. I. In vivo synthesis of connective tissue proteins. J Cell Biol 50:159–171
Salvatore CA (1962) The significance of the myometrial cell hypertrophy during pregnancy. Ergeb Allg Pathol Pathol Anat 42:148
Sharkey KA, Williams RG, Schultzberg M, Dockray GJ (1983) Sensory substance P-innervation of the urinary bladder: possible site of action of capsaicin in causing urine retention in rats. Neuroscience 10:861–868
Sibley GNA (1985) An experimental model of detrusor instability in the obstructed pig. Br J Urol 57:292–298
Speakman MJ, Brading AF, Gilpin CJ, Dixon JS, Gilpin SA, Gosling JA (1987) Bladder outflow obstruction — a cause of denervation super-sensitivity. J Urol 138:1461–1466
Steers WD, De Groat WC (1988) Effect of bladder obstruction on micturition reflex pathways in the rat. J Urol 140:864–871
Steers WD, Tuttle JB, Creedon DJ (1989) Neurotrophic influence of the bladder following outlet obstruction: implications for the unstable detrusor (abstract). Neurourol Urodyn 8:395–396
Susset JG, Servot-Viguier D, Lamy F, Madernas P, Black R (1978) Collagen in 155 human bladders. Invest Urol 16:204–209
Touloukian RJ, Spencer RP (1972) Ileal blood flow preceding compensatory intestinal hypertrophy. Ann Surg 175:320–325
Touloukian RJ, Aghajanian GK, Roth RH (1972) Adrenergic denervation of the hypertrophied gut remnant. Ann Surg 176:633–637
Uvelius B, Mattiasson A (1984) Collagen content in the rat urinary bladder subjected to infravesical outflow obstruction. J Urol 132:587–590
Uvelius B, Persson L, Mattiasson A (1984) Smooth muscle cell hypertrophy and hyperplasia in the rat detrusor after short-term infravesical outflow obstruction. J Urol 131:173–176
Uvelius B, Arner A, Malmqvist U (1989) Contractile and cystokeletal proteins in detrusor muscle from obstructed rat and human bladder. (Abstract) Neurourol Urodynamics 8:396–397
Wakade AR, Garcia AG, Kirpekar SM (1975) Effects of castration on the smooth muscle cells of the internal sex organs of the rat: influence of the smooth muscle on the sympathetic neurons innervating the vas deferens, seminal vesicle and coagulating gland. J Pharmacol Exp Ther 193:424–434
Webster W (1973) Embryogenesis of the enteric ganglia in normal mice and in mice that develop congenital aganglionic megacolon. J Embryol Exp Morphol 30:573–585
Wolinsky H (1970) Response of the rat aortic media to hypertension. Circ Res 26:507–522
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Gabella, G. Hypertrophy of visceral smooth muscle. Anat Embryol 182, 409–424 (1990). https://doi.org/10.1007/BF00178906
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00178906