Upsala J Med Sci 78: 167-168, 1973 Growth of Nervous Tissue in the Regenerated Rabbit Ear Chamber J. FALK, K.-E. ARFORS and F. N. McKENZIE From the Departments of Toxicology and Experimental Medicine, Pharmacia AB, Uppsala, Sweden, and Department of Surgery, University of Aberdeen, Aberdeen, Scotland ABSTRACT Highly specific nerve staining using thiocholine techniques has been applied to a study of nerve regeneration in tita- nium rabbit ear chambers. Early and extensive ingrowth of nerves rich in true cholinesterase activity was demon- strated. INTRODUCTION Since its description (lo), the regenerated rabbit ear chamber preparation has been extensively used in studies of vascular and cellular behaviour in the microcirculatory area of conscious animals. De- spite widespread use of the method, the question of innervation of the regenerated tissue has re- ceived scant attention. We considered it of in- terest, therefore, to briefly report our experience in applying modern histochemical techniques to a study of nerve ingrowth in chamber tissue. MATERIALS AND METHODS Titanium ear chambers were aseptically inserted into Sandy-Lop rabbits according t o the method previously described by Arfors et al. (1). Cholinesterase activity was displayed histochemically by Gomori's ( 6 ) modification of Koelle & Friedenwald's (8) method using ear chamber tissues of three weeks, two and four months of age. Normal rabbit ear perichondrium from the same rabbits treated in identical fashion t o the chamber tissue served as control. The tissues stained by the cholinesterase method were used fresh and were sufficiently thin (about 100 p m ) to obviate the need for sectioning. After excision of the ear chamber the top cover glass was removed and the regenerated tissue stained in situ o n the bottom plate. Incubation with acetyl thiocholine iodide as substrate was continued at 37°C for 18-24 hours. T o inhibit pseudo- cholinesterase and thus demonstrate true cholinesterase activity, a portion of e a r chamber tissue was pretreated with 1 x M tetraisopropylpyrophosphorarnide (ISO- OMPA, 3.42 mg/l of 40% sodium sulphate) for 30 min. The same concentration of 1.50-OMPA was included in Ihz incubation medium. During dehydration and clear- ing procsdures, the ear chamber and perichondrial tissues were kept under a cover glass to minimise tissue distor- tion. Nerve staining by silver impregnation was also done using a modification ( 5 ) of Bielschowsky's (2) method. In this instance prior fixation in 10% buffered formalin (pH 7.0) was required. The mounted preparations were viewed using transmit- ted or phase contrast light. Photographs were taken with a Reichzrt automatic camera using Kodak Ektachrome film. RESULTS Since the tissues used in this study were not sectioned, ingrowing nerves could be followed as uninterrupted dark brown lines. Occasional blood vessels could be faintly distinguished due to the presence of small amounts of pseudocholines- terase in the smooth muscle of the vascular wall. I n the three week old chamber, a single nerve trunk could be seen entering the chamber tissue. After giving off a small branch it extended some 2 mm towards the centre of the chamber. This regenerated nerve was shown to contain true cholinesterase; enzymatic activity persisted after inhibition of pseudocholinesterase by ISO-OMPA. Nerve regeneration followed a similar pattern and was developed to a similar extent in the two- and four-month-old ear chambxs. At both ages, the regenerated tissue was completely interwoven by a meshwork of nerve fibres with a maximal diameter of around 5 p m (Fig. 1). The larger nerves were seen to be made up of several neuro- fibrils and in this respect they resembled the nerves seen in perichondrial tissue. Not surpris- ingly, however, no thick nerve bundle entered the narrow chamber space, most being single fibrils which seemed to pursue a random course to cnd blindly in the chamber tissue or more often in relation to a blood vessel. The nerve fibres were Upsula J Med Sci 78 168 J . Falk et al. apparently unmyelinated but had an investing neurolemmal sheath. Schwann cell nuclei could be readily identified as local deviations of the neurofibrils but nodes of Ranvier were not ob- served. Silver impregnation of ear chamber tissue showed the striking development of the peri- vascular nerve plexus particularly well (Fig. 2 ) . Excessive and uneven staining with silver were, however, throublesome. DISCUSSION Using intravital staining with methylene blue dye, Clark et al. (3) demonstrated the ingrowth of an unmyelinated nerve accompanying an arteriole three weeks after insertion of a rabbit ear cham- ber. The present study using specific histochemical techniques confirms and extends these findings. The thiocholine method gives highly selective nerve staining, the only other deeply staining elements being fat cells, sebaceous glands and hair roots, none of which are found in regenerated chamber tissue. Arterial smooth muscle also shows some activity due to the presence of pseudocholin- esterase (4), but counterstaining is required to dis- play the vascular wall clearly. Our results show that differentiation of the capillary loops into definitive arterioles and venules is quickly fol- lowed by innervation of these structures. By two months a meshwork of ramifying nerve fibres has developed. True cholinesterase activity appears to be present from the outset and enzyme activity was evenly distributed along the nerve fibre. The staining features of the nerves suggest that they are postganglionic fibres of the autonomic ner- vous system. Most fibres terminate in relation to blood vessels but some nerve strands appear to end blindly, a n observation which was also made by Grant & Thompson (7) using normal rabbit ear preparations. Silver impregnation techniques suffer the dis- advantage when applied to ear chamber tissue that the abundance of reticular fibres may lead t o staining of non-nervous tissue with consequent difficulty in precise interpretation. However, as shown by Richardson (9) using rabbit intestinal tissue, silver staining was particularly useful in demonstrating the richness of the perivascular nervous network which quickly develops in ear chamber tissue (Fig. 2). As a final point it may be mentioned that the histological appearances of the derivatives of the different germ layers found in regenerated cham- ber tissue do not differ from that described in unspecialised connective tissue found elsewhere in the body. There seems, therefore, no a priori reason to presum- that the physiological responses observed in fully vascularised and stable ear chamber tissues should be atypical. REFERENCES 1. Arfors, K.-E., Jonsson, J. A. & McKenzie, F . N.: A titanium rabbit ear chamber: assembly, insertion and results. Microvasc Res 2: 516, 1970. 2. Bielschowsky, M.: Die silber Impragnation der Axen- cylinder. Neurologisches Centralblatt 21: 579, 1902. 3. Clark, E. R., Clark, E. L. & Williams, R. G.: Micro- 4. 5 . 6. 7. 8. 9. 10. scopic observations in the living rabbit of the new growth of nerves and the establishment of nerve- controlled contractions of newly formed arterioles. Amer J Anat 55:47, 1934. Coupland, R. E. & Holmes, R. L.: The use of cholin- esterase techniques for the demonstration of periph- eral nervous structures. Quart J Micr Sci 98: 327, 1957. Davenport, H. A., Windle, W. F. & Buch, R. H.: Block staining of nervous tissue. IV. Embryos. Stain Technology 9: 5, 1934. Gomori, G.: Microscopic histochemistry; principles and practice. The University of Chicago Press, Chicago, 1952. Grant, R. T. & Thompson, R. H. S . : Cholinesterase and the nerve supply to blood vessels in the rabbit’s external ear. J Anat (London) 97:7, 1963. Koelle, G. B. & Friedenwald, J. S . : A histochemical method for localising cholinesterase activity. Proc SOC Exp Biol Med 70:617, 1949. Richardson, K. C.: Studies on the structure of auto- nomic nerves in the small intestine correlating the silver impregnated image in light microscopy with the permanganate-fixed ultrastructure in electronmicro- scopy. J Anat (London) 94:457, 1960. Sandison, J. C.: A new method for the microscopic study of living growing tissues by the introduction of a transparent chamber in the rabbit’s ear. Anat Rec 28: 281, 1924. Received January 23, 1973 Address for reprints: Dr Karl-E. Arfors Department of Experimental Medicine Pharmacia AB Box 604 S-751 25 Uppsala 1 Sweden Upsala J Med Sci 78 Fig. 1. Thiocholine stain of four month old ear chamber Fig. 2. Silver impregnation of four month old ear chamber tissue showing the rich meshwork of regenerated nerve tissue showing the complex perivascular network of nerve fibres which develop, Phase contrast light linear magnifi- fibrils surrounding a 40 ,urn diameter venule. Transmitted cation x 275. light, linear magnification x 700. 1 I t - 732853 Upsala J Med Sci 78