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Previous Article | Next Article
The Journal of Neuroscience, August 15, 1999, 19(16):6965-6978
The Critical Period for Ocular Dominance Plasticity in the Ferret's Visual Cortex
Naoum P. Issa, Joshua T. Trachtenberg, Barbara Chapman, Kathleen R. Zahs, and Michael P. Stryker Keck Center for Integrative Neuroscience, Department of Physiology, University of California, San Francisco, California 94143-0444
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Microelectrode recordings and optical imaging of intrinsic signals were used to define the critical period for susceptibility to monocular deprivation (MD) in the primary visual cortex of the ferret. Ferrets were monocularly deprived for 2, 7 or >14 d, beginning between postnatal day 19 (P19) and P110. The responses of visual cortical neurons to stimulation of the two eyes were used to gauge the onset, peak, and decline of the critical period. MDs ending before P32 produced little or no loss of response to the deprived eye. MDs of 7 d or more beginning around P42 produced the greatest effects. A rapid decline in cortical susceptibility to MD was observed after the seventh week of life, such that MDs beginning between P50 and P65 were approximately half as effective as those beginning on P42; MDs beginning after P100 did not reduce the response to the deprived eye below that to the nondeprived eye. At all ages, 2 d deprivations were 55-85% as effective as 7 d of MD. Maps of intrinsic optical responses from the deprived eye were weaker and less well tuned for orientation than those from the nondeprived eye, with the weakest maps seen in the hemisphere ipsilateral to the deprived eye. Analysis of the effects of 7 d and longer deprivations revealed a second period of plasticity in cortical responses in which MD induced an effect like that of strabismus. After P70, MD caused a marked loss of binocular responses with little or no overall loss of response to the deprived eye. The critical period measured here is compared to other features of development in ferret and cat.
Key words: monocular deprivation; area 17; orientation; pinwheel; cortical columns; intrinsic signal imaging; strabismus
INTRODUCTION
The pathways that convey visual input to the primary visual cortex are precisely organized in normal adult mammals and have been extensively investigated in cats, monkeys, and ferrets. In the cat, precision in retinal and subcortical organization is attained before the end of the first week of postnatal life (Shatz, 1983
), at which time much of the specificity of cortical cell responses has yet to emerge. The development of precision in visual cortical responses and connections takes place in the context of functional inputs, allowing activity-dependent mechanisms to participate in this process. The influence of neural activity in the development of the visual cortex is most powerfully evident in the phenomenon of the "critical period", in which an alteration in the normal pattern of activity during a period in early life dramatically alters cortical inputs and responses, whereas a similar alteration later in life has no detectable effect (Wiesel and Hubel, 1963
The critical period for ocular dominance plasticity has been defined as the period of susceptibility to the effects of unilateral eye closure. Temporary monocular deprivation (MD) by unilateral eye closure during the critical period decreases the respon- siveness of cells in primary visual cortex (V1) to the deprived eye (Wiesel and Hubel, 1963
The ferret, because of the relative immaturity of its visual system at birth (Jackson and Hickey, 1985
The experiments presented here investigate the effects of monocular deprivation on the organization of the ferret primary visual cortex. First, the temporal extent of the critical period for ocular dominance column plasticity is determined. The critical period in ferret visual cortex begins well after the time at which visual responses may be elicited, and, as in other species, spans only a few weeks in neonatal life. Next, we describe a novel type of cortical plasticity in the adult ferret. Unlike monocular deprivation during the critical period, deprivations in the adult ferret produce a strabismus-like segregation of eye-specific responses without producing an overall shift in ocular dominance. Finally, the effects of monocular deprivation on the relationship between orientation columns and ocular dominance columns are studied. In the normal cat, peaks of ocular dominance columns are closely associated with centers of orientation pinwheels (Crair et al., 1997a
Some of this work has been presented in preliminary form (Chapman et al., 1996b
MATERIALS AND METHODS
Fifty-three black point sable ferrets were used for these experiments (9 normals, 44 monocularly deprived). All procedures were approved by the University of California at San Francisco Committee on Animal Research.
Monocular deprivation. Ferrets were anesthetized with 2% halothane in a 2:1 mixture of nitrous oxide-oxygen or 2.5% isoflurane in oxygen administered by face mask. After disinfecting skin around the eye to be deprived, eyelid margins were trimmed, chloramphenicol ophthalmic ointment (Parke-Davis, Morris Plains, NJ) was instilled in the eye, and the eyelids were sutured shut using two or three horizontal mattress stitches.
Surgical preparation. In preparation for electrophysiological recording or imaging, ferrets were anesthetized, and the primary visual cortex was exposed. Anesthesia was induced using a volatile agent (2% halothane in 2:1 nitrous oxide-oxygen or 2.5% isoflurane in oxygen). An intravenous catheter was inserted. Animals were placed on a regulated heating pad and maintained at core temperature of 37.7°C. Atropine (0.1 mg) and dexamethasone (0.4 mg) were administered subcutaneously to minimize tracheal secretions and stress responses. A tracheotomy was performed. Thereafter, animals were either maintained on 1-2% isoflurane in oxygen or infused intravenously with sodium thiopental and ventilated with 2:1 nitrous oxide-oxygen after discontinuing the inhaled anesthetic. Animals were then paralyzed with gallamine triethiodide (10 mg · kg
1 · hr
Once the level of anesthesia had reached surgical plane, animals were placed in a stereotaxic apparatus. Atropine sulfate (1% solution) and phenylephrine hydrocholoride drops (10% solution) were instilled into the eyes, and the eyes were fitted with contact lenses to prevent desiccation. Visual cortex was exposed through a craniotomy, and the dura mater was reflected using a dura hook. The exposed cortex was covered with a layer of low-melting point agarose (3% in standard saline).
Electrophysiology. Extracellular recordings of single and multiple units were made using resin-coated tungsten electrodes with tip resistances between 1 and 5 M
. Areas 17 and 18 meet near the midline of the lateral gyrus, area 17 running along the caudal surface of the gyrus, and area 18 along the rostral surface. To ensure that recordings were made from area 17, electrode penetrations were made in the caudal portion of the gyrus. For the majority of penetrations, differences in receptive field properties between areas 17 and 18, including size of receptive field and progression of visual fields, were used to verify that penetrations were in area 17. Oriented stimuli were generated with a hand lamp and presented first binocularly, then to each eye individually. Ocular dominance was classified based on the seven-point scale of Hubel and Wiesel (1962)
Whereas ocular dominance ranking classifies the ratio of contralateral to ipsilateral eye input to a single unit, the contralateral bias index (CBI) measures the degree to which the entire population of units is dominated by the contralateral eye. CBI is calculated as in Reiter et al. (1986
in which NT is the total number of visually responsive units and Nx is the number of units with ocular dominance rating x. A CBI of 0 indicates that the ipsilateral eye dominates the population of measured units, whereas a CBI of 1 indicates that the contralateral eye dominates the population. This index is designed so that a one-category error in the assessment of ocular dominance would cause the same change in the value of the CBI no matter in which ocular dominance category it occurs.
(1) Because monocular deprivation produces reciprocal shifts in CBI for the hemisphere ipsilateral and contralateral to the deprived eye, we used the difference in CBIs as a measure of the degree of shift. The shift index is defined as:
in which CBIipsi is the CBI of the hemisphere ipsilateral to the deprived eye and CBIcontra is the CBI of the hemisphere contralateral to the deprived eye. A shift index of +1 suggests that both hemispheres are entirely dominated by the nondeprived eye, whereas a shift index of
(2) 1 would mean that both hemispheres were entirely dominated by the deprived eye. This index has the advantage that a normal brain would be expected to have a shift index of 0, regardless of the normal CBI of the animal.
The CBI and shift index used here and in our earlier reports are similar in spirit to those used by other authors. For example, our CBI is equal to 1
The monocularity index (MI) reflects the degree to which cortical responses are dominated by one eye or the other but not by both (Stryker and Harris, 1986
An MI of 0 suggests that all individual cells are driven equally by both eyes, whereas an MI of 1 suggests that all cells are driven exclusively by one eye or the other.
(3) Throughout the text, all indices are expressed as a mean value ± the SE. Unless otherwise noted, the Mann-Whitney U test was used to test for statistical significance.
Histology. To determine the laminar position of recorded units, electrolytic lesions were made at defined locations along the electrode penetration. At the end of the recording session, a lethal bolus of thiopental was administered, and animals were perfused transcardially first with phosphate buffer, then with 4% paraformaldehyde. Brains were post-fixed in 4% paraformaldehyde for several days, then blocked and cut on a vibratome into coronal sections 50- to 70-µm-thick. Sections were mounted on glass slides and stained with cresyl violet. Laminar assignments were made from camera lucida drawings of the cortical laminae and lesions.
Imaging intrinsic signals. We imaged intrinsic signals from V1 and V2 in response to visual stimuli using the ORA 2001 Optical Recording Acquisition and Analysis System (Optical Imaging, Germantown, NY). Before imaging, a new layer of agarose and a cleaned coverslip were placed over visual cortex. The cortical surface was illuminated using a tungsten-halogen light source. Illumination wavelength was set using either a green (546 ± 10 nm) or red (610 ± 10 nm) interference filter. Initially, a green image of the surface vascular pattern was taken. The camera was then focused 400 µm below the pial surface, at approximately the depth of layer III. Images of intrinsic signals were acquired using the red filter for illumination, and an identical red filter was positioned between the brain and CCD camera. Full-field grating stimuli were produced by a VSG 2/3 board (Cambridge Research Systems, Rochester, UK) controlled by custom software. Gratings had a spatial frequency of 0.15 cycles/° and moved with a temporal frequency of 2 cycles/sec. Four to six cycles were visible on a 21 inch monitor (Nokia 445X) placed 40 cm from the animal. Stimuli moved in a direction perpendicular to the long axis of the grating, and reversed direction of motion every 2 sec. Stimulus orientation was selected pseudorandomly from four or eight evenly spaced templates spanning 180°; reversal of direction of motion gave the full 360° range of orientations. Four blank-screen stimuli (both eye shutters closed) were interleaved with the monocularly presented oriented stimuli; the average of the images collected during these blank-screen stimuli is the blank image. During a single stimulus presentation, 20 frames of 300 msec duration [CCD binning set to 2; 1 pixel = (16.7 µm)2] or 10 frames of 600 msec duration [CCD binning set to 1; 1 pixel = (22.5 µm)2] were acquired. The twelve or twenty conditions (4 orientations × 2 eyes + 4 blanks = 12 conditions, or 8 orientations × 2 eyes + 4 blanks = 20 conditions) were repeated 16 times to constitute a single run. Two to five runs were analyzed for each experiment. The illumination shutter, a Uniblitz VS35 shutter (Vincent Associates, Rochester, NY), and custom-built eye shutters were controlled by the stimulus and acquisition computers.
Images were analyzed using commercial (ORA 2000) and custom software written in the Interactive Data Language (Research Systems, Boulder, CO). Because the dominant component of the stimulus-induced intrinsic signal develops over 1-2 sec, the first 1.2 sec acquired under each condition were disregarded. The signal-to-noise ratio in images was improved by averaging the same condition over all remaining frames, repetitions, and runs. Images were then normalized either to the average of the four blank images (blank normalized) or to the average of all conditions except the blanks (cocktail-blank normalized). Ferret V1 is highly vascularized; areas of the image with vascular artifacts were removed by overlaying functional images with a template of the vascular pattern derived by digitally thresholding the average blank image (in which the surface vasculature is present but out of focus). Ocular dominance ratio maps showed the ratio between the average responses over all conditions for the two eyes. Angle and hue lightness saturation (HLS) maps were constructed as outlined in Bonhoeffer and Grinvald (1996)
An optical CBI was calculated from blank normalized images using a protocol slightly different from that of Crair et al. (1998)
in which PixelMax is the strongest response at a given pixel, and PixelEye2 is the pixel intensity for the same stimulus orientation as for PixelMax, but for the other eye. Because the images are blank-normalized, image intensities fluctuate around 1.0; the denominator therefore represent the difference between the response at the best orientation and the response to a blank screen. In some pixels in each image, the best response was smaller than or equal to the response to a blank screen; these pixels (always <10% of the total) were not included in the calculation of the CBI. The distribution of OD ratings for all pixels in the image was binned, and a weighted average was calculated to produce the Optical CBI ranging between 0 (for complete dominance of the ipsilateral eye) and 1 (representing complete dominance of the contralateral eye).
(4) For Monte Carlo simulations of the distance between ocular dominance column peaks and pinwheel centers (Crair et al., 1997a
RESULTS
Electrophysiological characterization of the ferret's ocular dominance critical period
To define the critical period for ocular dominance plasticity in the ferret's primary visual cortex, we assessed ocular dominance from extracellular responses in both normal and monocularly deprived ferrets. Ferrets ranging in age from postnatal day 19 (P19) through adult were monocularly deprived by lid suture for periods of 2, 7, or >14 d. A total of 2772 units were recorded in 51 animals: 1294 from the hemisphere ipsilateral to the deprived eye (or the right eye in normal animals) and 1478 from the contralateral (or left) hemisphere. Cells were classified based on their responses to each eye using the seven-point ocular dominance scale developed by Hubel and Wiesel (1962)
To ensure that the neurons sampled during electrophysiological recordings were in area 17, electrode penetrations were made in the caudal portion of the lateral gyrus, avoiding the more rostral area 18. The medial aspect of the dorsal portion of the lateral gyrus in most ferrets has a different arrangement of ocular dominance columns from the rest of area 17 (Rockland, 1985
Ocular dominance in normal animals was studied to establish baseline values of contralateral bias and monocularity. We studied seven animals ranging in age from P39 to adult (Fig. 1). As has been noted in young kittens (Crair et al., 1998
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Figure 1. Normal ocular dominance histograms. The number of recorded units with a given ocular dominance rating (1, dominated by contralateral eye; 7, dominated by ipsilateral eye) are plotted for young normal (P65 or younger) and mature normal ferrets (P80 or older). In both age groups, a large fraction of the recorded units are driven by both eyes. Young ferrets have a stronger bias toward the contralateral eye than do mature ferrets. The CBI and MI shown with each histogram are calculated from the distribution of units plotted. The values derived from these pooled histograms differ slightly from the CBIs and MIs given in Results; the indices in the text are averages of the CBI or MI from individual hemispheres.
To determine whether monocular deprivation during early life would have an effect on cortical responsiveness to the two eyes, nine animals were monocularly deprived for periods of 2 weeks or longer. Cortical responses in animals whose deprivation began at P30 were consistently shifted in favor of the nondeprived eye (n = 4; SI = 0.75 ± 0.10; Fig. 2B, dashed line; Table 1). In general, the hemisphere ipsilateral to the deprivation became almost entirely dominated by the nondeprived eye (CBI ipsilateral = 0.99 ± 0.01; Table 1), whereas the contralateral hemisphere retained a small amount of input from the deprived eye (CBI contralateral = 0.24 ± 0.09). Later deprivation was less effective in shifting cortical responses toward the open eye. Monocular deprivations begun on P114-116 (n = 2) or as adults (n = 2) appeared ineffective, yielding shift indices (SI = 0.01 ± 0.05) similar to those expected for normal ferrets.
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Figure 2. The effect of monocular deprivation on ocular dominance as a function of age. A, Ocular dominance histograms. Ocular dominance histograms are plotted for three ferrets that were monocularly deprived for 1 week starting at P35. Both the hemisphere ipsilateral to and that contralateral to the deprived eye were dominated by the open (nondeprived) eye. B, Shift index. Shift index is plotted as a function of age at the beginning of monocular deprivation. The shift index is the difference between the CBI of the hemisphere ipsilateral to the deprived eye and the CBI contralateral to the deprived eye. The larger the shift index, the greater the effect of monocular deprivation on ocular dominance. For all three series of deprivations (bold line, 7 d deprivations; solid line, 2 d deprivations; dashed line, >14 d deprivations), the shift index is greatest between P35 and P58, the peak of the critical period for ocular dominance plasticity in the ferret, indicated by the heavy line on the abscissa in parts B-D. The beginning of the critical period is defined by the age at which 2 d deprivations produce a shift index >0.5 (P35). The point at which the shift index for 7 d deprivations drops below 0.5 (P58) was taken as the end of the "peak" of the critical period. The size of a symbol is proportional to the number of animals that constitute each time point (Table 1). C, Contralateral bias index. The CBI for the series of 7 d MDs is plotted as a function of age at the beginning of monocular deprivation. Top line, CBI of the hemisphere ipsilateral to the deprived eye. Bottom line, CBI of the hemisphere contralateral to the deprived eye. Center line, Mean of the ipsilateral and contralateral CBIs. The CBI varies in a complementary fashion in the two hemispheres; both hemispheres become dominated by the nondeprived eye. Error bars indicate SEM; the circled point has only one hemisphere contributing to the CBI. D, Laminar analysis. The shift index for the series of 7 d MDs is plotted as a function of age at the beginning of monocular deprivation for each cortical layer. Cells in layer VI were the most affected by MD, whereas cells in layer IV were the least affected.
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Table 1. Effects of monocular deprivation of different durations as a function of age as measured by electrophysiology We used brief monocular deprivations to probe more precisely the extent of the critical period for ocular dominance. Twenty-three ferrets experienced 7 or 8 d of monocular vision beginning at ages ranging from P19 to P110. Monocular deprivations had a profound effect on cortical response properties when begun within the first 10 d after the time of natural eye opening (P32). Ocular dominance histograms from the two hemispheres of three ferrets deprived at P35 are shown in Figure 2A. A week of deprivation at P35 (SI = 0.83 ± 0.12) was as effective at shifting ocular dominance as deprivations of 2 weeks or longer that started at P30. In animals deprived starting around P42, the shift in ocular dominance was the largest observed of all age groups and durations, and represents a nearly complete shift to the nondeprived eye (SI = 0.90 ± 0.04).
The time course of the effect of 1 week of monocular deprivation on the ocular dominance response of cortical neurons is apparent in the shift indices and CBIs plotted in Figure 2, B and C. A week of deprivation produced little or no discernable shift when begun on or before P21 (SI = 0.05 ± 0.04; n = 5). After P42, monocular deprivations grew progressively less effective in altering cortical response properties. Monocular deprivations beginning around P60 were approximately half as effective as deprivations at the peak of the critical period, and monocular deprivations beginning after P100 failed to shift ocular dominance toward the open eye.
In cats, monocular deprivation for 2 d at the peak of the critical period results in a saturating shift in cortical response properties to favor the open eye (Hubel and Wiesel, 1970
To determine whether the magnitude of ocular dominance plasticity varied among cortical layers, we reconstructed electrode penetrations from histological sections of brains from animals that had been monocularly deprived for 7 d. Figure 2D shows the shift index of each lamina versus age at deprivation. As has been reported for other species (cat, Shatz and Stryker, 1978
MD in adult ferrets induces a strabismus-like effect in V1
The reduction in the response to the deprived eye that follows monocular deprivation during the critical period necessarily reduced the extent to which visual cortical neurons are driven binocularly. We measured the extent of monocular, as opposed to binocular, responsiveness by calculating the monocularity index for each cortical hemisphere (see Materials and Methods). In Figure 3, the monocularity index of the cortical hemispheres is plotted as a function of the age at deprivation. Deprivations initiated before the onset of the critical period produced little reduction in response to the deprived eye and left most cells with binocular responses, resulting in low values of the monocularity index (Fig. 3B). As expected, deprivations during the peak of the critical period caused a sharp increase in monocularity compared to normals (compare Figs. 2A, 1). Deprivations near the end of the peak of the critical period (~P58) produced a smaller increase in monocularity than did deprivations at the peak of the critical period (p < 0.025; comparing MIs for 7 d deprivations at P58 to those at P42).
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Figure 3. The effect of monocular deprivation on monocularity as a function of age. A, Ocular dominance histograms. Ocular dominance histograms are plotted for all units recorded from ferrets older than P86 that were deprived for 7 d or longer. The eyes are nearly equally represented in both hemispheres, but the fraction of monocularly dominated cells is greater than normal (compare with Figs. 1, 2A). This pattern is similar to that seen in strabismic animals. B, Monocularity index. The monocularity index for each series of monocular deprivations is plotted as a function of age at the beginning of deprivation. The monocularity index is a measure of how exclusively monocular a population of cells is: the larger the monocularity index, the fewer cells respond to both eyes. The 7 d (heavy solid line) and 2 d (solid line) MD series show two periods during which MD causes an increase in monocularity compared to normals (dotted line). The first period (~P35-P60) corresponds to the critical period (indicated by heavy line on abscissa here and in Fig. 2) during which changes in CBI are accompanied by an increase in MI. The second period, starting around P70 and extending into adulthood, is characterized by an increase in MI without a change in CBI. Dashed line, >14 d deprivations. Error bars indicate SEM; the circled point has only one hemisphere contributing to the monocularity index. C, Laminar analysis. The monocularity index for the series of 7 d MDs is plotted as a function of age at the beginning of monocular deprivation for each cortical layer. The laminar changes in monocularity index that occur during the critical period are analogous to the changes seen in ocular dominance; layer VI is the most affected and layer IV the least. After P70, MD produces large shifts to monocularity in layers II/III, IV, and VI, but little shift in layer V. The dip in monocularity index at P60 seen in the 2 d MD series (C) and in layers II-V in the 7 d MD series suggests that the strabismus-like effect of late MD is independent of the plasticity observed in the critical period.
Surprisingly, however, monocular deprivations beginning after the end of the critical period produced monocularity indices that were larger than both the MI found for deprivations at P58 (p < 0.05; comparing MIs for 7 d deprivations at P58 to those at P86) and the normal MI. Figure 3A shows that monocular deprivation after the peak of the critical period left the cortex with few cells that responded well to both eyes but similar numbers of cells dominated by the deprived and nondeprived eyes. Comparison with Figure 2A reveals that this effect is quite different from the loss of binocularity seen during the critical period. In eight animals, P84 or older, that were deprived for at least 7 d, the average monocularity index of 0.86 ± 0.02 (n = 15 hemispheres) was significantly different (p < 0.005) from that found in five normal animals (0.63 ± 0.06; n = 9 hemispheres). Such late MD produced little difference in contralateral bias between the hemispheres ipsilateral and contralateral to the deprived eye (SI = 0.09 ± 0.09; n = 7 deprived animals; compare to SI =
The extent to which monocular deprivation altered the cortical monocularity index decreased with age, but remained strong into adulthood. From ~P70-P90, 7 d deprivations were as effective as much longer deprivations in altering monocularity (Fig. 3B). In older animals, however, deprivations of 2 weeks or longer were necessary to increase monocularity. At ~P110, 7 d deprivations produced a monocularity index of 0.74 ± 0.03 (n = 3 hemispheres in two animals), whereas 40 d deprivations at P115 or older gave a monocularity index of 0.87 ± 0.02 (n = 8 hemispheres in four animals; 7 and 40 d deprivation effects are significantly different; p < 0.025). The time course of susceptibility to this strabismus-like effect of MD, increasing around P70 and decreasing around P110, is therefore different from that of the critical period. The effect of prolonged deprivation in older animals suggests that the adult cortex remains plastic.
A laminar analysis of monocularity suggests that the strabismus-like changes that occur during adulthood are not identical to the changes that occur during the critical period. Both the 7 d MD series (Fig. 3C) and the >14 d MD series (data not shown) have similar trends in the layers affected. During the critical period, cells in all layers became more monocular, with the most pronounced monocularity seen in layer VI. After a dip at the end of the critical period, layer IV became as monocular as layer VI, and layer V was less affected. The layer V finding is somewhat paradoxical, since layer V cells are the most affected after very long monocular deprivations (Shatz and Stryker, 1978
The relationship between the ocular dominance and orientation columnar systems in monocularly deprived ferrets
To assess the effects of monocular deprivation on the relationship between ocular dominance and orientation columns in the ferret, we imaged cortical activity in response to oriented gratings shown to one or the other eye. Confirming earlier reports, pinwheel structures, in which orientation preference varies continuously around a central point, were evident in the normal ferrets illustrated in Figure 4 (Chapman et al., 1996a
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Figure 4. Top. Ocular dominance and orientation maps in normal ferret visual cortex. Angle maps, in which hue represents the best angle to which cortex at a given pixel responds (see color bar), are shown for one adult ferret in A and C and one P71 ferret in D and F. A and D are constructed from images taken while stimulating the eye contralateral to the hemisphere, and C and F are from images taken while stimulating the ipsilateral eye. In each figure, the regions dominated by the stimulated eye have well organized orientation pinwheels; the regions dominated by the unstimulated eye have little organization. B and E are ocular dominance ratio maps constructed by dividing the activity in the contralateral maps (A, D) by the ipsilateral maps (C, F). Dark regions represent cortex dominated by the contralateral eye, and light regions represent cortex dominated by the ipsilateral eye. The values listed next to the grayscale calibration bar represent the range of intensity modulation around the cocktail blank value of 1.0. Portions of both areas V1 and V2 are shown. Vascular artifacts are overlaid with background color. Scale bar, 1 mm (in all panels).
Figure 5. Bottom. The effects of monocular deprivation on optical maps of ferret visual cortex. A-E are from an animal in which monocular deprivation produced a large shift in ocular dominance as measured electrophysiologically (animal F309C, SI = 0.90, deprived at P30 for 19 d). F-J are from an animal in which monocular deprivation produced no electrophysiologically measured shift in ocular dominance (animal F322E, SI =. Peaks of nondeprived-eye columns are plotted as
, and peaks of deprived-eye columns are plotted as x. Local extrema in the ocular dominance map were selected as peaks of ocular dominance columns. There is no consistent relationship between the positions of ocular dominance peaks and pinwheel centers in either the strongly shifted (C) or the unshifted (H) cortex. In C, intensity ranges from
For animals in which monocular deprivation produced a significant shift in the electrophysiologically measured contralateral bias index, the optical responses were also abnormal. The effects of monocular deprivation on optical maps depended strongly on the age at the onset of deprivation. Figure 5 contrasts optical maps from an animal with a large shift in ocular dominance after MD (A-E, F309C; SI = 0.90; 19 d MD beginning at P30) with maps from an animal that did not have an ocular dominance shift (F-J, F322E; SI =
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Table 2. Comparison between electrophysiological and optical imaging measures of the effects of monocular deprivation In the cat, monocular deprivation causes most of the cortex to lose strong responses from the deprived eye, whereas neurons in the patches of cortex that retain strong responses to the deprived eye largely lose selectivity for stimulus orientation (Crair et al., 1997b
Intrinsic signal-imaging experiments on monocularly deprived cats also found that most of the patches of strong cortical responses to the deprived eye were located near pinwheel centers (Crair et al., 1997b
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Figure 6. Monte Carlo analysis of pinwheel-peak distances. To determine whether pinwheel centers in the ferret are closer to peaks of ocular dominance columns than would be expected by chance, we performed a Monte Carlo analysis of distances between pinwheel centers and ocular dominance peaks. The positions of pinwheel centers and ocular dominance peaks were determined for each hemisphere imaged. The distance between each ocular dominance peak and its nearest pinwheel center was measured. The distributions of pinwheel-peak distances were grouped by developmental stage and eye stimulated. Group 1, Critical period animals stimulated through the deprived eye (x); group 2, critical period, nondeprived eye ( ). For each group, the cumulative distribution is plotted against distance. For the Monte Carlo analysis, each imaged hemisphere was treated individually: the same number of pinwheels as was in the original image was placed randomly on the image, whereas ocular dominance peaks were not moved. The distributions of distances produced from 5000 simulations on each map were grouped into a single cumulative distribution (solid line). There was no statistical difference between any of the four distributions and their image-appropriate Monte Carlo distribution (Kolmogorov-Smirnov one-sample test; p > 0.05).
One reason that the relationship between ocular dominance peaks and orientation pinwheels in the ferret may differ from that of the cat is that there are many more pinwheels than ocular dominance peaks in the ferret, whereas the numbers of these two features are similar to one another in the cat (Crair et al., 1997a
DISCUSSION
The critical period for ocular dominance plasticity in the ferret
We have characterized the time course of the effect of monocular lid suture on ocular dominance plasticity in the ferret. Cortical susceptibility to monocular deprivation begins around P35, a few days after natural eye opening, and peaks around P42.The critical period in the ferret therefore has a clear beginning that is later than the time at which neurons in the visual cortex begin to respond well to visual stimulation. In the present experiments, no ocular dominance shifts were found in 411 units recorded in eight animals in which monocular deprivation ended before postnatal day 30 (2 d MD at P28 and 7 d MD at P19 and P21; Table 1). By P30, responses of visual cortical neurons are strong, despite the fact that most neurons lack orientation selectivity (Chapman and Stryker, 1993
As has been found in other species (LeVay et al., 1978
The duration of deprivation had a profound effect on the extent of cortical changes. While 7 d deprivations were sufficient to induce a saturating shift in ocular dominance, 2 d deprivations were ~70% as effective. The ferret cortex therefore changes more slowly in response to monocular deprivation than does the cat cortex, in which 2 d of deprivation produces a saturating ocular dominance shift (Crair et al., 1997b
The larger average size of ferret ocular dominance columns means there is less border length between opposite-eye columns in a given area of ferret cortex than in cat cortex. If changes in ocular dominance proceed along ocular dominance column borders, the smaller border length in the ferret may slow the overall progress of ocular dominance changes. NMDA receptors, which have been implicated in cortical plasticity associated with MD in vivo (Kleinschmidt et al., 1987
Strabismus-like changes in the adult
Monocular deprivation that starts after the critical period causes an effect like that of strabismus in the ferret visual cortex. After late-onset deprivation, each eye is represented to a normal extent in V1, but few cells are driven by both eyes. In earlier studies in other species, such a shift to monocularity was associated with strabismus during the critical period (Hubel and Wiesel, 1965
A loss of binocularity has also been observed in cats that were monocularly deprived either very briefly or at the end of the critical period (Hubel and Wiesel, 1970
A pattern of age-dependent deprivation effects similar to that observed in the ferret was seen by Kasamatsu et al. (1979)
The finding that monocular deprivation can produce a strabismus-like pattern of cortical activity may be relevant to a type of secondary strabismus found in humans after prolonged monocular deprivation by cataract. Studies in nonhuman primates suggest that visual deprivation can cause strabismus. Various protocols of monocular deprivation begun near the time of birth of a monkey can produce interocular misalignment (Quick et al., 1989
Intrinsic signal imaging
We assessed the effects of monocular deprivation on orientation and ocular dominance maps by imaging intrinsic cortical signals. Maps of V1 and V2 from monocularly deprived ferrets were consistent with the findings of monocular deprivation studies in cat (Crair et al., 1997b
Given the lack of coincidence of ocular dominance peaks and pinwheel centers in the normal ferret, it is not surprising that there is no clear relationship after monocular deprivation. In both cats and ferrets, deprived-eye patches lose their orientation selectivity. In the deprived cats, however, the deprived-eye patches are even closer to the pinwheel centers than in normal animals. Crair et al. (1997b)
Comparison with the development of the cat
Figure 7 summarizes several milestones in the development of the ferret and cat visual systems (with references given in the figure) in relation to the critical period defined in this report. The rates of development of the cat's and the ferret's visual systems are generally similar starting from the day of conception rather than the time of birth (Linden et al., 1981
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Figure 7. Timeline of developmental milestones in the visual system; comparison of the ferret to the cat. Developmental milestones in the visual cortex, LGN, and retina are displayed for both species. The development of the ferret's visual system has been thought to proceed with the same postconception time course as that of the cat. Several events, however, occur earlier in the ferret than in the cat. In addition to an earlier beginning to the critical period and ocular dominance segregation, cortical horizontal connections begin to cluster earlier, most cortical cells are born earlier, and LGN lamination, axonal growth, and cortical invasion occur earlier in the ferret than in the cat. Other subcortical developmental time points are more closely matched between the two species. OD, Ocular dominance; MD, monocular deprivation; GC, ganglion cell; C-I, contralateral-ipsilateral. References: 1, Hubel and Wiesel (1970)
FOOTNOTES Received April 6, 1999; revised May 20, 1999; accepted May 21, 1999.
This work was supported by National Institutes of Health Grant EY02874 (M.P.S.) and National Research Service Award postdoctoral fellowships (N.P.I. and J.T.T.). Michael Crair provided software for both stimulus generation and image analysis. Members of the Stryker lab provided helpful discussion and comments on this manuscript.
N.P.I. and J.T.T. contributed equally to this work.
Correspondence should be addressed to Prof. Michael P. Stryker, Department of Physiology, Room S-762, 513 Parnassus Avenue, University of California, San Francisco, CA 94143-0444.
Dr. Chapman's present address: Center for Neuroscience, University of California, Davis, CA 95616.
Dr. Zah's present address: Department of Physiology, University of Minnesota, Minneapolis, MN 55455.
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