1. A description is provided of the changes in area, wet weight, and collagen content of the scar left by a small skin wound in young adult rats during the period between 15 days and 300 days after wounding. The corresponding changes in normal skin were also followed.

  2. A standard square area of skin of about 20 mm.2 was marked by tattooing on the back of each of a number of rats, averaging about 250 g. in body-weight. The area was then excised and its collagen content estimated by the hydroxyproline technique of Neuman & Logan (1950). The wound was allowed to heal without dressing. At 15, 50, 100, 200, and 300 days after wounding groups of the animals were killed, the scars measured, and their hydroxyproline content estimated. Control areas of normal skin, similarly tattooed at the same time as the wounded area, were measured in the 100-, 200-, and 300-day groups, and excised for collagen estimation at the same time as the scars.

  3. After the period of contraction and the following phase of stationary area, which according to previous work lasts until about 25 days after wounding, the scar starts to expand, and probably continues to do so throughout the period of observation. The expansion is rapid at first, but diminishes in rate. An initially comparable area of normal skin also grows throughout at a diminishing rate per day, but, at least up to about 50 days after wounding, at a lower rate per unit of area already present than the scar.

  4. The wet weight of the scar increases proportionately to its increase in area. The wet weight of normal skin probably increases a little faster than its area, and the wet weight per unit of area of normal skin eventually surpasses that of the scar.

  5. Collagen formation in the scar probably occurs throughout the period of scar expansion, at such a rate as to increase the content per unit of area and of wet weight. Normal skin is at the same time also increasing its collagen content per unit of area and of wet weight, but not so fast as the scar. Consequently by about 50 days the scar concentration per unit of wet weight or of area has caught up with that of control skin; by 100 days the scar clearly surpasses the normal skin in collagen per unit of wet weight, and by 200 days in collagen per unit of area.

  6. The growth of the scar is interpreted according to the hypothesis of Billingham & Medawar (1955), as a response to tension.

A PREVIOUS paper (Abercrombie, Flint, & James, 1954) described the early changes in size and collagen content of the granulation tissue and subsequent scar that fill a small wound made in the dorsal skin of a rat. The observations were carried up to the 25th day after wounding. It was found that by about the 10th day the wound had contracted down to a minimal area and wet weight, and that it remained at or near this minimum during the remaining 15 days of observation. The collagen content of the repair tissue increased during the phase of contraction and continued to do so in the completely contracted wound. In the present paper we describe the later evolution of the scar up to 300 days after wounding. The reduced area and wet weight reached by 10 days have proved to be merely temporary minima. A phase of growth of the scar follows. Our previous suggestion that collagen formation may continue beyond 15 days after wounding turns out to be correct, but something of an understatement: at least ten times as much collagen is formed after 15 days as before.

Animals

Adult male white rats were used, of a mean body-weight of 243 ·7 g., range 182–321, standard deviation 35· 1. They were divided into five treatment groups, differing in length of time (15,50,100,200, or 300 days) between wounding and autopsy. Tattooing and operation were performed on fourteen batches each of five rats. Each batch contributed to two different treatment groups. The number of animals finally available for analysis in each treatment group was as follows: at 15 days, 10; at 50 days, 8; at 100 days, 13; at 200 days, 10; and at 300 days, 10. Body-weight at the time of operation did not differ significantly between the treatment groups (the variance between groups being less than the variance within groups). Mean body-weight gains during the experiment were: 15-day group 36 ± 3; 50-day group 103 ± 8; 100-day group 176 ± 9; 200-day group 118 ± 26; and 300-day group 205 ± 20. The 200-day group is anomalous because it contained four members of one batch the whole of which failed almost completely to grow.

Tattooing and operation

Techniques were much the same as those used previously (Abercrombie, Flint, & James, 1954). A machine with eight needles was, however, used to make a tattoo pattern of eight dots, describing a square of approximately 25–30 mm.2 in area (measured through the dot centres) in the skin to one side of the midline of the dorsolumbar region. The marks were driven by the needles almost down to the deep fascia. Within this tattoo pattern bordered by the dots, a square about 20 mm.2 in area of the full thickness of the skin was excised. In the 100,200, and 300-day groups a second, control square, which remained unwounded, was tattooed on the other side of the dorsal midline, so that the normal growth in area of the skin could be assessed. The size and disposition of the tattoo marks were reproduced on tracing-paper before operation and before autopsy. In the 100 and 300-day groups tracings were also made at intermediate times, enabling us to follow the evolution in area of individual wounds and control areas. The areas marked out by the tattoos were measured from the tracings by the photoelectric method as previously described. Excision, both during the initial wounding and during the final removal of the scar and control area at autopsy, was made within the inner margins of the tattoo dots, after the skin had been treated with cedar-wood oil to make the dots as clear as possible. The margin of normal skin, which was usually apparent, was an additional guide to the excision of the scars. It is difficult to excise the scar accurately within the eight dots when it is at its minimum size, so that the 15-day group is doubtless less reliable than the later groups. The excised pieces—the initial piece of normal skin removed at operation, and the scar and control piece of normal skin removed at autopsy— were weighed wet, and their collagen was estimated by the hydroxyproline technique of Neuman & Logan (1950). Results of the latter estimation are given in microgrammes of hydroxyproline.

The degree of standardization attained in making the initial wounds is shown by the area, weight, and hydroxyproline content of the pieces removed (Table 1). It is evident that the different treatment groups are not homogeneous. The 15,50, and 200-day groups are fully comparable with each other; but, because of a temporary defect in the spacing of the tattooing needles, the 100 and 300-day groups, though they do not differ significantly from each other, differ from the other three groups in that they have received on the average larger wounds. This failure of randomization must be taken into account in assessing the results. On the other hand, within each of the groups, the area of skin removed at the operation did not differ significantly from the corresponding control areas at that time. The mean area (in mm.2) within the tattoos in the 100-day group was 20·8 ± 0·8 and 20·4 ±1 ·1 on repair and control sides respectively; in the 200-day group 17·1±0·5 and 16·3± 0· 9; and in the 300-day group 22·7 ±1·5 and 22·2 ± 0·9.

TABLE 1

Mean area, wet weight, and hydroxy proline content ( with standard errors) of the pieces of normal skin removed at initial operation in the five groups of rats killed at different intervals of time afterwards

Mean area, wet weight, and hydroxy proline content ( with standard errors) of the pieces of normal skin removed at initial operation in the five groups of rats killed at different intervals of time afterwards
Mean area, wet weight, and hydroxy proline content ( with standard errors) of the pieces of normal skin removed at initial operation in the five groups of rats killed at different intervals of time afterwards

The composition of the skin at the time of the operation did not differ between the groups: wet weight or hydroxyproline content when standardized for area by analysis of covariance, and hydroxyproline content when similarly standardized for wet weight, do not differ significantly between the groups (P > 0·2).

Stability of tattoos

The tattoo marks were not the only guide to measurement and excision of a scar, since the boundary between normal skin and scar could usually be seen. We depended, however, entirely on the tattoo marks for determining the amount of control skin to be excised. We assume therefore that the marks have adequate stability; and the long periods of time make it necessary to examine whether we can rely on this. During the experiment each dot enlarged slowly in surface area, as is to be expected from the general growth of the skin. This general growth can be assessed from the growth of the area enclosed by a line drawn through the centres of the dots: an area which should be unaffected by independent changes in dot size. The actual change in dot size proved to be larger in some groups and smaller in others than was to be expected from the general growth of the skin. The discrepancy, though consistent within any one group at successive times, did not amount to more than 10 per cent, of the area demarcated by the dot centres. Change in either direction is probably due to dispersion of the carbon particles, which can be seen to have occurred in sections: a little dispersion spreads the dot; much dispersion dilutes its periphery so that it appears to shrink. The same methods of estimating the instability of the marks cannot be applied to the tattoo marks at the edge of the wound, because it is not known what allowance should be made here for growth of the skin within which the marks are embedded.

We have not attempted to follow quantitatively the vertical distribution of the tattoo marks. In sections of marks in unwounded skin and during the first 25 days after wounding the marks extend almost or quite through to the subcutaneous tissue beneath the panniculus carnosus. At the 100th day after wounding the depth of the marks is approximately the same in sections. By gross inspection during excision it is still the same at the 300th day. Throughout the period the marks seemed to remain substantially vertical to the skin surface.

Area of scar

It was obvious by simple inspection that by the 15th day after operation the wounds had contracted, assuming the usual shape of a 4-pointed star (Abercrombie, Flint, & James, 1954); and that they subsequently expanded again, without however reverting towards their original square shape. The control areas equally obviously had grown throughout the period of observation.

These growth changes are expressed in Table 2 by measurements of the area enclosed by the dot centres. Any changes in dot size, provided they take place symmetrically, which they seem to do, are thereby made irrelevant. The disadvantage of this method of measurement, when applied to the wounded side, is that it does not express changes in size of the scar alone, but of the scar together with a surrounding rim of original skin, representing the radius of the dots, which contributes significantly to the total area when the scar is small. Such measurement are best made successively on the same animals, to avoid superimposing variation between animals on variation between times. We therefore quote only mean tattoo areas of the members of the 100-day group (group A) and of the 300-day group (group B), which were measured at intervals: the 100-day group at 15,30,60, and 100 days; the 300-day group at 15,50,100, and 300 days. There is progressive growth of the control tattoo area. After the very sharp contraction of the wounded tattoo area, there is an expansion, rapid at first, then slower. Since growth-curves based on means have undergone a statistical smoothing out, which may disguise the real course of events during the growth of an individual, we should add that the size changes of the individual scars follow the same pattern.

TABLE 2

Mean tattoo areas (measured through centres of tattooed dots), with standard errors, in two groups of rats (A, 9 rats; B, 10 rats) each rat bearing a wounded and a control area; measured at successive times after wounding

Mean tattoo areas (measured through centres of tattooed dots), with standard errors, in two groups of rats (A, 9 rats; B, 10 rats) each rat bearing a wounded and a control area; measured at successive times after wounding
Mean tattoo areas (measured through centres of tattooed dots), with standard errors, in two groups of rats (A, 9 rats; B, 10 rats) each rat bearing a wounded and a control area; measured at successive times after wounding

There are changes in amount of growth per day during the period of scar expansion. When the two groups are combined, the growth per day of the tattooed area of the wounded side between 15 and 50–60 days is 0·202 ± 0·015 mm.2; between 50–60 and 100 days it is 0 ·048 ± 0·011 mm.2; and (in the 300-day group only) between 100 and 300 days it is 0· 029 ± 0 ·005 mm.2 Measurements of the areas within the inner borders of the tattoo points, representing the size of the scar itself qualified by errors due to change of dot size, also follow the same pattern: growth per day between 15 and 50–60 days is 0·134 ± 0 ·011 mm.2; between 50–60 and 100 days it is 0 ·044 ± 0· 009 mm.2; and between 100 and 300 days it is 0 ·017 ±0·044 mm.2 There is evidently therefore a well-marked decline with time in the growth rate of the scar. There is a similar decline in growth per day of the control area, which between 15 and 50–60 days is 0·170 ±0 ·027 mm.2; between 50–60 and 100 days 0· 094 ±0·025 mm.2; and between 100 and 300 days 0 ·043 and 0· 008 mm.2

The absolute amount of new area added per day is rather similar whether the tattoo encloses a scar or an area of normal skin. Over the whole of the first 100 days after wounding the addition of new area is negligibly different between wounded and control sides (10·3 ± 0·7 mm.2 and 11·1 ± 1·3 mm.2 respectively). But though the means are so similar, the wounded side is less variable than the control: the variances are indeed significantly different (F = 3·45, d.f. 18 and 18, 0·05 >P>0·01). The similarity of the wounded and control sides in the absolute addition of new area implies a great difference in growth rate, since the area on the wounded side has been initially much reduced by contraction. In terms of specific growth rate, the wounded area grows highly significantly faster than the control up to 50 to 60 days, but thereafter there is no significant difference.

Shape of scar

The original tattoo mark describes a square with two sides parallel to the long axis of the animal. Contraction of the wound converts the square into a symmetrical 4-pointed star as described by Abercrombie, Flint, & James (1954), but the set of corner dots and the set of mid-side dots continue each to mark out an approximate square. The contraction (during the first 15 days) occurring between the corner dots in the direction along the length of the animal does not differ significantly from the contraction transverse to the length of the animal: the difference between these contractions is 0·17 ±0·16 mm. The subsequent expansion of the scar is, however, slightly asymmetrical. The longitudinal expansion (between corner dots, during the period of 15 to 100 days) is greater than the transverse expansion. The difference between them (0·35 ± 0·16 mm.) is only of border-line significance (t 2·17, d.f. 19, P = 0·05); but if the expansion is expressed as relative to the length of side at 15 days, the difference becomes highly significant it 3·26, d.f. 19, P < 0· 01). Furthermore, the degree of stellateness is slightly reduced in the longitudinal direction, the distance between the mid-side points increasing rather more than that between the corner points during the period from 15 to 100 days; while in the transverse direction the degree of stellateness slightly increases. The difference is just significant at the 5 per cent, level.

The control area has no tendency to take up a stellate form but it does not remain a square. During the period of contraction of the wound it becomes elongated towards the wound. Between 0 and 5 days its length in the longitudinal axis of the animal diminishes, and its length in the transverse axis increases, the difference between the changes in the two axes (0·52 ± 0·18 mm.) being significant (t 2·94, d.f. 19, P < 0 ·01). Between 15 and 100 days this initial distortion is a little reduced: like the scar, the control area grows somewhat more in the longitudinal than in the transverse direction. Unlike the scar, the difference between growth in the two directions is not significant, perhaps because the linear growth of the control skin is in absolute terms less than that of the scar, and hence more obscured by errors of observation. We have investigated whether asymmetry of scar growth is correlated with asymmetry in control area growth within individual animals. Using the growth between 15 and 100 days, relative to the length of side at 15 days, and expressing the asymmetry as before by subtracting the growth in the longitudinal direction from that in the transverse direction, we obtained a correlation coefficient between scar and control area of +0·431 (d.f. 18), which is almost significant at the 5 per cent, level. There is here, therefore, a suggestion of a common response of scar and normal skin to factors influencing the pattern of growth.

Wet weight

There are greater uncertainties about the analysis of the wet-weight changes of the scar than of its area changes. This is partly because of the greater technical difficulty of measuring wet weight; and partly because we are obviously unable to follow wet weight in the same group of rats through the time course of repair but must use a succession of different groups of rats.

The mean weights of the excised scars are given in Table 3, col. 4. There is evidently a sharp rise in weight between 15 and 50 days after wounding, and then a suggestion of an upward trend continuing to the end of the longest period observed. As mentioned in the section on Method, however, the different groups were not satisfactorily standardized for the size of the initial wound. Adjustment of the mean weights by analysis of covariance to allow for the variation in initial wound area does not, however, seriously alter the picture. The adjusted means for the five successive time groups are respectively 4 9,14·4,14·3,18 ·8, and 19·8. We have tested whether there is a significant rise in weight in the period from 50 to 300 days by regressing the wet weight at autopsy against time, using multiple regression analysis to remove any effects of the non-homogeneity of initial area. The partial regression coefficient in microgrammes of wet weight per day is 27·8 ±11·8 it = 2 ·35, d.f. 39, 0 ·05 > P > 0· 02). The relation with initial wound area is not significant. The areas of the scars are also given in Table 3 (col. 3), and it is evident that the growth in weight corresponds to the growth in area. Weight per unit area (col. 5) does not change significantly with time.

TABLE 3

Measurements (means and standard errors) made on scars N = number of animals, HYP = hydroxy proline

Measurements (means and standard errors) made on scars N = number of animals, HYP = hydroxy proline
Measurements (means and standard errors) made on scars N = number of animals, HYP = hydroxy proline

The uninjured skin on the control side grows in area, as already discussed, and in wet weight also (compare the initial weight of the skin within the tattoo mark on the operated side, Table 1, col. 4, with the final weight on the control side, Table 4, col. 4). It furthermore appears that in normal skin there is a slight increase with time in weight per unit area. This only emerges significantly if we standardize the data by taking for each rat the difference between weight per unit area at initial operation and weight per unit area at autopsy. Pooling the data Of the 100-, 200-, and 300-day groups the increase (0·22 ±0· 09) is just significant (t = 2·31, d.f. 32,0 ·05 > P > 0· 02). Evidently thickening of the skin with age is much less well marked than is growth in area. The weight per unit area of the scar (Table 3, col. 5) is significantly less (at the 1 per cent, level) than that of the normal skin (Table 4, col. 5) of the same animals, taking the 100-, 200-, and 300-day groups separately. Exactly comparable normal skin is not available for the 15 and 50-day groups.

TABLE 4

Measurements (means and standard errors) made on control areas of normal skin in three groups of rats. The areas were marked at the beginning of the experiment and removed at the time of excision of the scars

Measurements (means and standard errors) made on control areas of normal skin in three groups of rats. The areas were marked at the beginning of the experiment and removed at the time of excision of the scars
Measurements (means and standard errors) made on control areas of normal skin in three groups of rats. The areas were marked at the beginning of the experiment and removed at the time of excision of the scars

Hydroxyproline content

Like the measurements of wet weight, those of hydroxyproline content are relatively less efficient than are the area measurements because the time-course has to be constructed from successive groups of animals. Table 3 (col. 6) gives the mean total amount of hydroxyproline in the scar at different times after wounding. There appears to be a sharp rise in hydroxyproline content between 15 and 50 days, followed by a steady upward trend. Adjusting the means by covariance analysis to remove the effects of differences in initial wound-size does not alter this picture: the means of the five successive times groups become 90, 409, 505, 765, and 885 respectively. The difference between any successive two of these means, apart from that between the 15-and 50-day means, is not significant or is only just significant at the 5 per cent, level. When, however, the change in hydroxyproline content between 50 and 300 days is analysed by multiple regression, with time since wounding and initial wound size as variables, the regression on time is highly significant (the partial regression coefficient, in microgrammes hydroxyproline per day, is 2 ·00 ±0·44, t = 4·52, d.f. 39, P < 0·001). The regression on initial wound size is not significant. We may conclude that collagen is laid down during most or all of the time covered by our experiments. In earlier work (Abercrombie, Flint, & James, 1954) we found the mean hydroxyproline content of similar wounds at 15 days to be 143 ± 23 μg., almost twice the value now obtained. The discrepancy is undoubtedly due to the use of 4-point tattoos for the earlier paper, which, as there discussed, leads to the inclusion of serious amounts of normal skin.

The increase of hydroxyproline content with time is accompanied, as we have already shown, by an increase in area and wet weight of the scar. The formation of hydroxyproline proceeds rather faster, however, than does weight and area increase. There is an increase of hydroxyproline per unit area (Table 3, col. 7), which is obvious between 15 and 50 days, and can be shown between 50 and 300 days by regression against time (the regression coefficient in μg. hydroxyproline per mm.2 per 100 days is 7·05 ±2·36, t = 2·98, d.f. 40,0·01 >P>0·001). Since it has been shown that weight per unit area does not change significantly with time, it is not surprising to find that the concentration of hydroxyproline per unit weight (Table 3, col. 8) increases significantly with time. There is no need to test the obvious significance of the increase between 15 and 50 days. Between 50 and 300 days regression against time shows a significant rise (the regression coefficient in μg. hydroxyproline per mg. per 100 days is 5·33 ±1·41, t = 3·8, d.f. 40, P< 0 ·001).

Evidently (col. 6 of Tables 1 and 3) at some time between 100 and 200 days the collagen originally removed has been replaced. During this period, however, a comparable area of normal skin has been growing not only in area and wet weight but also in total hydroxyproline content (compare Table 4, col. 6 with Table 1, col. 6). In normal skin, as in the scar, the laying down of collagen proceeds faster than the growth of area, so that the hydroxyproline content per unit area increases (Table 4, col. 7). The increase is not as clear as it is in the scar: the regression coefficient of hydroxyproline per unit area against time is not quite significant at the 5 per cent, level. The normal skin at the end of the experiment in the 100-, 200-, and 300-day groups of rats has, however, in each group significantly more hydroxyproline per unit area (Table 4, col. 7) than the corresponding samples of normal skin taken from the same three groups of rats at the beginning of the experiment (Table 1, col. 7). For the difference within the 100day group, t = 3·28, d.f. 24, P < 0· 01; for the 200-day group t = 2·36, d.f. 18, 0 ·05 > P > 0· 02; and for the 300-day group t = 3·84, d.f. 19, P < 0· 01. A progressive but small increase in hydroxyproline per unit area seems the most likely interpretation. We have already shown that normal skin is probably increasing, too, in weight per unit area (presumably representing thickness), and this almost accounts for the increase in hydroxyproline per unit area; there is no sign of any change in concentration per unit of wet weight with time in the three control groups (Table 4, col. 8). When, however, the concentrations found in these three control groups are pooled and compared with the concentrations found in the same rats at the beginning of the experiment (Table 1, col. 8), a significant difference can be demonstrated 0 = 3· 10, d.f. 32, P < 0· 01). The increase in hydroxyproline in relation to the weight or area of tissue available to form it is obviously much higher in the scar than in the normal skin, since the wounded area after its contraction is throughout smaller than the control area.

The final comparison to be made is between the concentrations of hydroxyproline in scar and in normal skin. The hydroxyproline per unit area or weight is obviously much less in a scar at 15 days than in the skin in which the wound was made (Tables 3 and 1, cols. 7 and 8). The lack of strict control skin taken at autopsy precludes any definite conclusions for the 50-day group but the concentration in the scar does not differ from that of the controls of the 100-, 200-, and 300-day groups; it seems likely therefore that the scar concentration has by 50 days caught up with that of normal skin. By 100 days the concentration per unit area in the scar obviously does not differ from that of the normal control skin (col. 7 of Tables 3 and 4), but the concentration per unit weight (col. 8) in the scar has surpassed that of normal skin (t = 3·30, d.f. 24,0· 01 > P > 0·001). By 200 days the scar concentration is higher both in terms of area and of weight; for area it is significantly so if the variance between rats is eliminated (t = 3 ·13, d.f. 9, 0 ·02 > P > 0·01), for weight it is obviously significantly higher. By 300 days the superiority of the hydroxyproline concentration of the scar in terms of both weight and area is clear enough to need no statistical testing.

The present work describes the evolution in size and collagen content of the scar left by a small skin wound during the period between 25 and 300 days after the injury. We do not yet know how representative the description we have presented is of skin wounds in general, so it is necessary to keep in mind the type of operation we have used. The wounds were small, square, full-thickness excisions made in a region of rather mobile skin in young adult rats, and left undressed.

Before surveying the changes in size and collagen content of the scar we must describe the background of change in the control area of normal skin during the same period of time. It is remarkable that the control area, situated 2–3 cm. from the wound, is nevertheless detectably distorted by the contraction of the latter. It is legitimate to assume that the contraction is the cause of the distortion, because no further distortion occurs when contraction ceases. Evidently a pull is exerted over an unexpectedly wide area around the wound, and there must be some caution about interpreting the control areas as fully representative of normal skin. The continuous growth in skin area no doubt reflects the continuous growth in body-weight of the rats, and the decline in the rate of growth of skin area expresses the ordinary decline of specific growth-rate with age, though the high rate in the 50 days immediately after operation may be partly a response to the distortion caused by the contraction. The growth in skin area is accompanied by a small increase in skin thickness, as indicated by changes in weight per unit area. Collagen is laid down in amounts slightly more than is required to keep pace with the growth in area and thickness so that there is a small rise in concentration per unit area and per unit of wet weight.

We turn now to consider the growth of the material filling the wound. The period up to 25 days after wounding can be divided into three phases, according to the data of Abercrombie, Flint, & James (1954). (1) Up to 5 days, granulation tissue is forming beneath the scab, the wound diminishes slightly in area, and a small amount of collagen is laid down. (2) Between 5 and 10 days rapid contraction occurs, diminishing the area by more than a half. This is a process in which the original cut edges of the wound are drawn inwards by a shrinkage of the wound content, the motive power being supplied, we have suggested (Abercrombie, Flint, & James, 1956), by the cells. Collagen formation continues during this phase. (3) Between 10 and 25 days the wound area is approximately stable. Since we have three successive measurements at 10, 15, and 25 days on each member of a group of animals, we know that this pause is not an artifact due to a statistical smoothing out of mass data. Collagen formation continues during this phase, too; but by the end of it the concentration of collagen in the contracted scar is still much below that of normal skin, whether expressed per unit of wet weight or per unit of superficial area.

Our present results show that a fourth phase then starts, and continues for as long as our observations have been carried. It is a phase of expansion of scar area, probably very rapid at first. Wet weight increases at the same pace, so there is probably no significant change in thickness of the scar. Collagen is laid down at a high rate per day during the period of rapid increase of area, though our data do not allow us to say that the rate is any different from that obtaining during the earlier phases of stationary or contracting area. It is formed in the scar at a higher rate per unit area or per unit of wet weight than it is at the same time being formed in the rest of the animal’s skin, so that concentration of scar collagen increases steadily in relation to that of normal skin. It probably reaches the normal value, in terms either of wet weight or of area, by about 50 days. This accords well with the time of return of tensile strength to normal (Howes, 1954).

The increase in area and wet weight, initially so fast, diminishes in absolute amount added per day. Wet weight per unit area remains stable, in contrast to normal skin which is slowly growing in thickness. However, the scar continues at least for some time to lay down more collagen per day than an equivalent area of normal skin. By 100 days, therefore, the scar has surpassed normal skin in collagen per unit of wet weight; and by 200 days, in spite of the greater thickness of normal skin, in collagen per unit area too.

The later changes of collagen content here described merely put into quantitative terms the ‘collagenization’ of a scar which is qualitatively familiar to pathologists. What could not be demonstrated for certain from histological sections is now established for the rat, that these late changes in a scar involve more than mere packing together of existing collagen: they involve continuous new formation of collagen.

Abercrombie, Flint, & James (1954) pointed out that during the first 25 days after wounding the formation of collagen did not parallel the process of contraction. They were therefore led to reconsider the accepted theory that contraction is produced by newly formed collagen (Abercrombie, Flint, & James, 1956). The present work merely serves to reinforce our previous doubts. Collagen formation occurs continuously through the phases of contraction, of minimal area, and of expansion: it could hardly be less closely correlated with contraction.

A phase of scar expansion following the phase of contraction has been observed before in the course of experimental work (Carrel & Hartmann, 1916; Clark, 1919) though apparently long-term measurements of the phenomenon have not previously been made. Its interpretation, we believe, should be on the lines suggested by Billingham & Medawar (1955). They found that an island of skin left in the middle of a raw area, or a skin graft placed there, underwent a remarkable increase in size, which they suggested was a growth response to the tension set up by the process of contracture. They further suggested that the earlier reported instances of scar expansion might have the same explanation; and that the post-natal growth of normal skin may be adjusted to the size of the animal by a similar response to tension. Our observations on the changes in shape of the tattoo patterns during their expansion readily fall into place in this hypothesis. In the rat wounds that we have investigated the scar expansion is perhaps unusually conspicuous and long-continued because of the continuous growth in bulk of the whole animal, which superimposes a tension generated by growth on the tension generated by contraction. But a lesser degree of scar expansion may be of general occurrence. When contraction reduces a wound to little more than a linear scar, as it does in rabbits (Billingham & Reynolds, 1952; Billingham & Russell, 1956 a, b) subsequent expansion may be negligible, most of the adjustment to tension occurring by intussusceptive growth of the surrounding normal skin (Billingham & Medawar, 1955). But even in rabbit scars expansion may become obvious when contraction fails to go to completion (Billingham & Russell, 1956a).

We wish to express our gratitude to Professor J. Z. Young for reading the manuscript; to Miss Sylvia Jenkins for technical assistance; and to the Nuffield Foundation for their financial help.

Abercrombie
,
M.
,
Flint
,
M. H.
, &
James
,
D. W.
(
1954
).
Collagen formation and wound contraction during repair of small excised wounds in the skin of rats
.
J. Embryol. exp. Morph
.
2
,
264
-
74
.
Abercrombie
,
M.
,
Flint
,
M. H.
, &
James
,
D. W.
(
1956
).
Wound contraction in relation to collagen formation in scorbutic guineapigs
.
J. Embryol. exp. Morph
.
4
,
167
75
.
Billingham
,
R. E.
, &
Medawar
,
P. B.
(
1955
).
Contracture and intussusceptive growth in the healing of extensive wounds in mammalian skin
.
J. Anat. Lond
.
89
,
114
23
.
Billingham
,
R. E.
, &
Medawar
,
P. B.
&
Reynolds
,
JOYCE
(
1952
).
Transplantation studies on sheets of pure epidermal epithelium and on epidermal cell suspensions
.
Brit. J. plast. Surg
.
5
,
25
36
.
Billingham
,
R. E.
, &
Medawar
,
P. B.
&
Russell
,
P. S.
(
1956a
).
Incomplete wound contracture and the phenomenon of hair neogenesis in rabbits’ skin
.
Nature, Lond
.
177
,
791
2
.
Billingham
,
R. E.
, &
Medawar
,
P. B.
(
1956b
).
Studies on wound healing with special reference to the phenomenon of contracture in experimental wounds in rabbits’ skin
.
Ann. Surg
.
144
,
961
81
.
Carrel
,
A.
, &
Hartmann
,
A.
(
1916
).
Cicatrization of wounds. I. The relation between the size of a wound and the rate of its cicatrization
.
J. exp. Med
.
24
,
429
50
.
Clark
,
A. H.
(
1919
).
The effect of diet on the healing of wounds
.
Bull. Johns Hopkins Hosp
.
30
,
117
-
20
.’
Howes
,
E. L.
(
1954
).
The connective tissues in wound healing
. In
Connective Tissue in Health and Disease, ed
.
G.
Asboe-Hansen
.
Copenhagen
:
Ejnar Munksgaard
.
Neuman
,
R. E.
, &
Logan
,
M. A.
(
1950
).
The determination of collagen and elastin in tissues
.
J. biol. Chem
.
186
,
549
56
.