Changing Parental Knowledge and Treatment Acceptance for ADHD: A Pilot Study.

This pilot study assessed the feasibility and potential effectiveness of a single-session workshop in modifying parental beliefs/knowledge about attention-deficit/hyperactivity disorder (ADHD) in children and impact on treatment acceptance/utilization. Concerns raised by school professionals about lack of treatment follow-through after ADHD diagnosis and parental misinformation about medication usage catalyzed this project. A single-group pre-post quasi-experimental design was used. Sixty-eight parents completed ADHD knowledge/belief scales and stress inventories, and pre-ADHD and post-ADHD information workshop. Follow-up calls were made after the workshop to assess treatment utilization. Parents/caregivers experienced significant knowledge and belief changes regarding medication efficacy, willingness to accept physician treatment recommendations, and rejection of non-empirically based treatments. Follow-up data showed that 41% of contacted participants met with physicians to discuss medication utilization and behavioral treatments. Brief, one-session psycho-educational workshops were feasible and impacted parental beliefs and behaviors regarding scientifically supported interventions for ADHD.

Selective destruction of nerve growth factor receptor-bearing cells in vitro using a hybrid toxin composed of ricin A chain and a monoclonal antibody against the nerve growth factor receptor.

A hybrid toxin composed of ricin A chain and a monoclonal antibody directed against the rat nerve growth factor (NGF) receptor (192-IgG) was prepared using the heterobifunctional cross-linking agent N-succinimidyl-3-(2-pyridyldithio)-propionate and purified by affinity chromatography. Characterization studies showed that the hybrid, 192-s-s-A, displaced bound 125I-labeled 192-IgG from rat superior cervical ganglion (SCG) membranes with an IC50 3-5 times lower than that of unconjugated 192-IgG. When incubated with cultured rat SCG neurons, 192-s-s-A inhibited protein synthesis in a concentration-dependent fashion. The effect of 192-s-s-A on these neurons was reversed by coincubation with an excess of 192-IgG. The IC50 of 192-s-s-A on protein synthesis in rat SCG neurons was 4 nM. Intact ricin and ricin A chain inhibited protein synthesis in these neurons with IC50 values of 5 pM and 500 nM, respectively. The 192-s-s-A hybrid had no effect on mouse SCG neurons or a human melanoma cell line known to have NGF receptors. This is consistent with the finding that 192-IgG recognizes only the rat NGF receptor. Also, 192-s-s-A did not inhibit protein synthesis in primary cultures of rat skeletal muscle or Vero cells, which do not have cell surface receptors for NGF. 192-s-s-A was able to inhibit protein synthesis in PC12 cells but the potency was 10-100 times less in these cells compared to rat SCG neurons. Ricin and A chain were also 10-100 times less potent in PC12 cells than neurons. Rat SCG neurons exposed to 192-s-s-A lost their refractile appearance under phase-contrast optics, showed granular degeneration of neurites, and died. Thus the decreased protein synthesis caused by the hybrid toxin correlated with the morphological destruction of the neurons. 192-s-s-A represents a potentially powerful tool by which to selectively destroy NGF receptor-bearing cells in vitro. The hybrid toxin may prove useful as an in vivo toxin.

Insulin receptors: differences in structural organization on adipocyte and liver plasma membranes.

Comparison was made of the distribution of the insulin receptor sites on adipocyte and liver plasma membranes by using ferritin-insulin. Two-thirds of the occupied insulin receptors on adipocytes occurred in groups of two or more whereas up to two-thirds of the receptors on liver occurred as single receptors. Ferritin-insulin did not cause aggregation of the receptor sites in either tissue. The naturally occurring groups of receptors on adipocyte membranes may play a role in the greater sensitivity of adipocytes to insulin.

Heterogeneity of subcellular localization of p53 protein in human glioblastomas.

Immunohistochemical analysis of the p53 protein in human glioblastomas with known genetic profiles of p53 mutations and allele losses on chromosome 17p demonstrated a heterogeneous pattern of subcellular compartmentalization of the p53 protein. Tumors with a single wild type copy of the p53 gene but with allelic deletions on chromosome 17p exhibit nuclear and/or cytoplasmic accumulation of p53, whereas tumors with both copies of the wild type gene and no allele losses on chromosome 17 do not accumulate p53. Glioblastomas with one normal and one mutated copy of the p53 gene and allelic deletions on 17p distal to p53, on the other hand, show predominantly cytoplasmic staining, probably originating from the wild type p53 protein. Furthermore, tumors with mutations in the same codon of p53 display quite different intracellular distribution suggesting that, in addition to the genotype of p53, the intracellular microenvironment of a particular tumor is important in determining the subcellular localization of the p53 protein.

A trial-by-trial analysis reveals more intense physical activity is associated with better cognitive control performance in attention-deficit/hyperactivity disorder.

Hyperactivity is a key symptom and the most observable manifestation of attention-deficit/hyperactivity disorder (ADHD). The over-activity associated with ADHD can cause specific challenges in academic settings, extracurricular activities and social relationships. Cognitive control challenges are also well established in ADHD. The current study included 44 children between the ages of 10 and 17 diagnosed with ADHD or who were typically developing (TD), all of whom had no psychiatric co-morbidity or significant learning disorders. Participants wore an actometer on their ankle while performing a flanker paradigm in order to objectively measure their rates of activity in association with cognitive control. Analyses assessed the relationship between frequency and intensity of activity to task accuracy on a trial-by-trial basis. A significant interaction effect between group and performance revealed that more intense movement was associated with better performance in the ADHD group but not in the TD group. The ADHD group demonstrated more intense activity than the TD group during correct (but not error) trials. Within-group, children with ADHD generated higher intensity movements in their correct trials compared to their error trials, whereas the TD group did not demonstrate any within-group differences. These findings suggest that excessive motoric activity associated with clinically significant ADHD symptoms may reflect compensatory efforts to modulate attention and alertness. Future research should systematically explore the relationship between motion in ADHD and how it might be used to improve cognitive performance.

Neural activity related to drug craving in cocaine addiction.

BACKGROUND: Crack cocaine dependence and addiction is typically associated with frequent and intense drug wanting or craving triggered by internal or environmental cues associated with past drug use. METHODS: Water O 15 positron emission tomography (PET) studies were used to localize alterations in synaptic activity related to cue-induced drug craving in 8 crack cocaine-dependent African American men. In a novel approach, script-guided imagery of autobiographical memories were used as individualized cues to internally generate a cocaine craving state and 2 control (ie, anger and neutral episodic memory recall) states during PET image acquisition. RESULTS: The mental imagery of personalized drug use and anger-related scripts was associated with self-ratings of robust drug craving or anger, and comparable alterations in heart rate. Compared with the neutral imagery control condition, imagery-induced drug craving was associated with bilateral (right hemisphere amygdala activation greater than left) activation of the amygdala, the left insula and anterior cingulate gyrus, and the right subcallosal gyrus and nucleus accumbens area. Compared with the anger control condition, internally generated drug craving was associated with bilateral activation of the insula and subcallosal cortex, left hippocampus, and anterior cingulate cortex and brainstem. A brain-wide pixel-by-pixel search indicated significant positive and negative correlations between imagery-induced cocaine craving and regional cerebral blood flow (rCBF) in distributed sites. CONCLUSIONS: The collected findings suggest the craving-related activation of a network of limbic, paralimbic, and striatal brain regions, including structures involved in stimulus-reward association (amygdala), incentive motivation (subcallosal gyrus/nucleus accumbens), and anticipation (anterior cingulate cortex).

192 IgG-saporin: I. Specific lethality for cholinergic neurons in the basal forebrain of the rat.

An immunotoxin (IT) composed of a monoclonal antibody to the nerve growth factor (NGF) receptor, 192 IgG, chemically linked to saporin, 192 IgG-saporin, was shown to selectively reduce forebrain choline acetyltransferase (ChAT) activity in the rat brain following intraventricular administration. In order to determine if the IT was killing NGF receptor-positive neurons in the CBF (rather than simply suppressing the cholinergic phenotype in these cells), a population of neurons in the nucleus basalis magnocellularis (NBM) was prelabeled by an intracortical injection of the neurotracer Fluoro-Gold (FG) 1 week before intraventricular injections of IT or control substances (reduced IT or phosphate-buffered saline). We found that there were very few double-labeled (i.e. FG-labeled and ChAT-positive) neurons remaining in the NBM of IT-treated animals. The absolute number of FG-labeled neurons in the NBM of IT-treated animals was reduced by a number similar to the counts of double-labeled neurons in the NBM of control animals. Our conclusion is that the IT is preferentially lethal to cholinergic neurons in the NBM. Due to its ability to selectively kill cholinergic neurons in the CBF and concomitantly spare noncholinergic neurons with similar morphology and projections, 192 IgG-saporin can be used to produce a selective model of CBF deficit in the rat.

Alterations in the functional anatomy of working memory in adult attention deficit hyperactivity disorder.

OBJECTIVE: The authors used a functional neuroimaging study with a working memory probe to investigate the pathophysiology of attention deficit hyperactivity disorder (ADHD). Their goal was to compare regional cerebral blood flow (rCBF) changes related to working memory in adults with and without ADHD. METHOD: Using [(15)O]H(2)O positron emission tomography (PET) studies, the authors compared the sites of neural activation related to working memory in six adult men diagnosed with ADHD and six healthy men without ADHD who were matched in age and general intelligence. RESULTS: Task-related changes in rCBF in the men without ADHD were more prominent in the frontal and temporal regions, but rCBF changes in men with ADHD were more widespread and primarily located in the occipital regions. CONCLUSIONS: These data suggest the use of compensatory mental and neural strategies by subjects with ADHD in response to a disrupted ability to inhibit attention to nonrelevant stimuli and the use of internalized speech to guide behavior.

Receptor-mediated retrograde transport in CNS neurons after intraventricular administration of NGF and growth factors.

Radiolabel tracer techniques were used to follow the distribution of nerve growth factor (NGF) and other neuromodulatory factors after intraventricular injection. Autoradiography showed that shortly after intraventricular injection of radio-iodinated NGF (125I-NGF), substantial amounts of radioactivity had penetrated the ventricular wall surfaces; this binding was transient and nonspecific. The 125I-NGF was progressively cleared from the central nervous system (CNS), presumably via the flow of cerebrospinal fluid (CSF) into the blood. A relatively small proportion of the injected 125I-NGF was taken up by NGF receptor-positive neurons in the CNS. Retrograde accumulation of radiolabel was observed within the basal forebrain cholinergic neurons at 5 hours after intraventricular injection. Labeling intensity was maximal at 18 hours and much reduced by 30 hours. This labeling was blocked by co-injection of an excess of unlabeled NGF. Specific and saturable retrograde labeling was also observed within other NGF receptor-bearing neurons, including the prepositus hypoglossal nucleus and the raphe obscurus nucleus. When epidermal growth factor (EGF), transforming growth factor-beta 1 (TGF-beta 1), platelet-derived growth factor-AA (PDGF-AA), PDGF-BB, leukemia inhibitory factor (LIF), insulin-like growth factor-I (IGF-I), or IGF-II was radiolabeled and injected intraventricularly, specific labeling of neurons was observed for 125I-IGF-II and 125I-LIF within separate subpopulations of the dorsal and medial raphe. No retrograde accumulation within neurons was observed for EGF, TGF-beta 1, PDGF-AA, PDGF-BB, or IGF-I. This study describes an in vivo method for identifying putative neuromodulatory factors and their responsive neurons.

Effects of cholinergic depletion on experience-dependent plasticity in the cortex of the rat.

Clinical and functional studies have strongly suggested that acetylcholine input from the nucleus basalis of Meynert is important for the cortex's adaptive response to experience. The purpose of this study was to investigate the effects of depletion of acetylcholine inputs from nucleus basalis of Meynert on experience-dependent plasticity in the cortex of young adult male rats. The posteromedial barrel subfield in the primary somatosensory cortex was studied. Experience-dependent plasticity was elicited using a whisker-pairing paradigm in which all whiskers except D2 and D3 were trimmed daily. Plasticity within barrel D2 of the posteromedial barrel subfield was measured using the electrophysiological extracellular recording technique. An index of plasticity was determined in two ways: as an increase in the magnitude of evoked activity to stimulation of whisker D2 and as a bias in the ratio of evoked activity for stimulation of paired whisker D3 and cut whisker D1 (D3/D1). Whiskers D2, D3 and D1 were stimulated (deflected) by a Chubbuck electromechanical stimulator. Cholinergic neurons in the nucleus basalis of Meynert were selectively lesioned with an immunotoxin, 192 IgG-saporin, injected into the left lateral ventricle. Lesions of cholinergic neurons in the nucleus basalis of Meynert were verified using choline acetyltransferase immunocytochemistry and radioenzymatic assay. Experience-dependent plasticity was significantly reduced in cholinergic-depleted animals. The magnitude of evoked activity to stimulation of whisker D2 increased by 16-100% in control animals compared with 0-20% in cholinergic-depleted animals. Similarly, compared to a 60-100% increase in the D3/D1 ratio of evoked activity for phosphate-buffered saline-injected control animals, cholinergic-depleted rats showed no significant increase in the D3/D1 ratio (0-15%) after undergoing the whisker-pairing paradigm. After whisker trimming, the D3/D1 response ratio in immunotoxin-treated animals was essentially the same as in control animals that had not been subjected to the whisker-pairing paradigm. This study showed that no significant plasticity response was observed in the absence of cholinergic input from the nucleus basalis of Meynert. The mechanisms of the action of acetylcholine in cortical plasticity are still not known, but we hypothesize that this type of plasticity is activity dependent and is significantly enhanced in the presence of acetylcholine.

The impact of hypercarbia on the evolution of brain injury in a porcine model of traumatic brain injury and systemic hemorrhage.

Carbon dioxide is perhaps the most potent available modulator of cerebrovascular tone and thus cerebral blood flow (CBF). These experiments evaluate the impact of induced hypercarbia on the matching of blood flow and metabolism in the injured brain. We explore the hypothesis that hypercarbia will restore the relationship of CBF to metabolic demand, resulting in improved outcome following traumatic brain injury (TBI) and hemorrhage. A behavioral outcome score, hemodynamic, metabolic, and pathologic parameters were assessed in anesthetized and ventilated juvenile pigs. Animals were assigned to either normocarbia or hypercarbia and subdivided into TBI (via fluid percussion) with or without hemorrhage. The experimental groups were TBI; TBI + 40% hemorrhage (40%H); TBI + hypercarbia (CO2); and TBI + 40%H + CO2. Hemorrhaged animals were resuscitated with blood and crystalloid. Hypercarbia was induced immediately following TBI using 10% FiCO2. The normocarbic group demonstrated disturbance of the matching of CBF to metabolism evidenced by statistically significant increases in cerebral oxygen and glucose extraction. Hypercarbic animals showed falls in the same parameters, demonstrating improvement in the matching of CBF to metabolic demand. Parenchymal injury was significantly decreased in hypercarbic animals: 3/10 hypercarbic versus 6/8 normocarbic animals showed cerebral contusions at the gray/white interface (p = 0.05). The hypercarbic group had significantly better behavioral outcome scores, 10.5, versus 7.3 for the normocarbic groups (p = 0.005). The decreased incidence of cerebral contusion and improved behavioral outcome scores in our experiments appear to be mediated by better matching of cerebral metabolism and blood flow, suggesting that manipulations modulating the balance of blood flow and metabolism in injured brain may improve outcomes from TBI.

Secondary neurologic injury resulting from nonhypotensive hemorrhage combined with mild traumatic brain injury.

Although the emergency physician often treats patients with multiple injuries, there are relatively few clinically relevant models that mimic these situations. To describe the changes after a hemorrhagic insult superimposed on traumatic brain injury (TBI), anesthetized and ventilated juvenile pigs were assigned to 35% hemorrhage (35H), TBI (via fluid percussion); TBI + 35H, and TBI + 40H (40% hemorrhage). Animals were resuscitated with shed blood and crystalloid. Hemodynamic, metabolic, behavioral, and histologic parameters were assessed for 48 h. In TBI, mean arterial pressure (MAP) was not significantly different from baseline. For TBI + 40H, MAP fell by 60% (p < 0.05). This was corrected with resuscitation. Interestingly, TBI + 35H did not show a fall in MAP, while in 35H, MAP was reduced similarly to the TBI + 40H group. ICP was elevated only initially in the TBI group. In TBI + 40H and TBI + 35H, ICP increased markedly with resuscitation, remaining elevated for 60 min. ICP remained at baseline with 35 H. Hemorrhagic focal cerebal contusions at the gray-white interface were observed in 3/5 of TBI + 40H and 5/7 of TBI + 35H. Despite the presence of subarachnoid hemorrhage (SAH) in all the animals in the TBI alone group, none of these animals demonstrated grossly discernible intraparenchymal injury. There was no evidence of intracranial injury in the 35H group. Only in animals receiving a secondary insult of hemorrhage following the primary TBI were cerebral contusions found. These experiments demonstrate the evolution of cerebral contusions as a form of secondary neurologic injury following resuscitation from traumatic brain injury and hemorrhage, even in the absence of significant blood pressure changes.

Early assessment of neurologic deficits in the fluid percussion model of brain injury.

This study was designed to quantify the early neurologic effects of brain injury elicited by fluid percussion to the dura of cats. Propofol was used for surgical anesthesia because recovery in normal animals from an intravenous infusion was found to be nearly complete within 2 h of cessation and absolutely complete by 4 h. In addition, a cat coma scale (CCS) was developed that reflects normal (CCS, 14) to moribund (CCS, 3) behavior. The CCS values at 6 h were compared with the force of injury expressed in atmospheres (atm), maximum blood pressure change, and gross neuropathology to ascertain which parameter might best account for the behavior observed after brain injury. The results showed that decreasing neurologic scores correlated well with increasing atmospheres of injury (Pearson's r 0.71, p < 0.001) but not with the rise in systolic blood pressure caused by the trauma (n = 29). Coma scores did correlate with the cross sectional area of ponto-mesencephalic lesions (Pearson's r = 0.51, p < 0.01) and proved to be significantly different in animals grouped according to lesion size of less or more than 3 mm in length (t test, p < 0.01). Thus the CCS and the pharmacologic properties of propofol permit an early analysis of the neurologic status in the feline fluid percussion model of brain injury. These procedures could facilitate the evaluation of early biochemical changes that affect behavior and of therapies designed to ameliorate the deleterious effects of head injury.

Immunohistochemical detection of a monoclonal antibody directed against the NGF receptor in basal forebrain neurons following intraventricular injection.

It has been shown by autoradiography that, following intraventricular administration, a monoclonal antibody directed against the rat nerve growth factor (NGF) receptor is specifically accumulated bilaterally by numerous cholinergic neurons of the basal forebrain. This is consistent with the evidence that cholinergic basal forebrain neurons have NGF receptors and respond to NGF under a variety of experimental conditions. The present study demonstrates that the immunohistochemical detection of unmodified monoclonal antibody in cholinergic forebrain neurons following transport from CSF is feasible, although injection of larger amounts of the antibody is required to obtain an image equivalent to the one obtained with the autoradiographic method. The location of the immunohistochemical product clearly indicates that the antibody has been internalized, probably in an endosomal compartment.

Nerve growth factor receptor-mediated transport from cerebrospinal fluid to basal forebrain neurons.

Recent data indicate that the neurons of the cholinergic basal forebrain (CBF) respond to nerve growth factor (NGF) with increased survival under experimental conditions and have NGF receptors which mediate the binding and retrograde transport of NGF from axon terminals to somata. Focal intraparenchymal injections of retrograde tracing agents into neuropil demonstrate that the distribution of axons from cholinergic nuclei to cortex and hippocampus is topographically restricted and largely ipsilateral. Monoclonal antibody 192, a well-characterized antibody which recognizes only the rat NGF receptor, was labelled with 125I and injected into a lateral ventricle of adult rats. Highly specific bilateral transport to numerous neurons of the CBF system was demonstrated by autoradiography. This result directly demonstrates that suitably targeted antibodies can be taken up by specific neuronal populations following intraventricular injection and implies that CBF neurons may be influenced by relatively high molecular weight substances injected into cerebrospinal fluid.

Nerve growth factor receptor-mediated transport from CSF labels cholinergic neurons: direct demonstration by a double-labeling study.

It has recently been shown that, following intraventricular administration, a monoclonal antibody directed against rat nerve growth factor (NGF) receptor is specifically accumulated bilaterally by numerous neurons of the basal forebrain. The labeled neurons have a morphology and topography which are characteristic of the magnocellular cholinergic basal forebrain (CBF) system. This is also consistent with the evidence that CBF neurons have NGF receptors and respond to NGF in a variety of experimental situations. In the present report, a double-labeling technique is used to directly demonstrate that choline acetyltransferase-containing (and therefore cholinergic) neurons do in fact accumulate the anti-NGF receptor antibody from CSF.

Effects of cholinergic depletion on neural activity in different laminae of the rat barrel cortex.

The purpose of these experiments was to determine the effects of cholinergic depletion on spontaneous and evoked activity of neurons in the different layers of the posteromedial barrel subfield (PMBSF) of the rat somatosensory cortex. Acetylcholine neurons in nucleus basalis of Meynert (NBM) were selectively lesioned with an immunotoxin (IT), 192 IgG-saporin. Spontaneous activity was significantly lower in layers II-III, Va, and VI in IT-injected animals compared to control animals. Evoked activity was significantly lower in layers II-III, IV, Vb, and VI of IT-injected animals compared to control animals. The largest difference was observed in layer Vb. Thus, cholinergic depletion causes significant changes in the magnitude of spontaneous and evoked activity but these differences are not completely in register with one another.

Specificity of 192 IgG-saporin for NGF receptor-positive cholinergic basal forebrain neurons in the rat.

A monoclonal antibody to the rat nerve growth factor (NGF) receptor, 192 IgG, accumulates bilaterally and specifically in cholinergic basal forebrain (CBF) cells following intraventricular injection. An immunotoxin composed of 192 IgG linked to saporin (192 IgG-saporin) has been shown to destroy cholinergic neurons in the basal forebrain. We sought to determine if intraventricular 192 IgG-saporin affected choline acetyltransferase (ChAT) enzyme activity in the CBF terminal projection fields. ChAT assays from 192 IgG-saporin-treated animals showed significant time-dependent decreases in ChAT activity in the neocortex, olfactory bulb and hippocampus, compared to PBS- or OKT1-saporin-injected controls. ChAT and tyrosine hydroxylase activity in the striatum was always unchanged by 192 IgG-saporin. ChAT immunohistochemistry was confirmative of major cell loss in the CBF, while other cholinergic nuclei appeared unremarkable. The data provide further evidence of the selectivity of 192 IgG-saporin in abolishing cholinergic, NGF receptor-positive CNS neurons.

The effects of immunolesions of nerve growth factor-receptive neurons by 192 IgG-saporin on sleep.

Low-affinity nerve growth factor (NGF) receptors are present on the cholinergic neurons of the basal forebrain. We studied the effects of 192 IgG-saporin, a specific immunotoxin for the NGF receptor-positive, cholinergic basal forebrain neurons, on sleep, the power spectrum of the electroencephalogram (EEG), and body temperature. After 3 d baseline recordings, 12 male rats were injected intracerebroventricularly with 4 micrograms 192 IgG-saporin. EEG, motor activity, and brain temperature were recorded for 23 h on the first, third, fifth, and seventh day after the treatment. 192 IgG-saporin did not affect the total daily amounts but altered the circadian distribution of sleep. On days 1 and 3 after the injection of the immunotoxin, the amount of non-rapid-eye-movement sleep (NREMS) and rapid-eye-movement sleep (REMS) increased during the dark period, whereas during the light both NREMS and REMS decreased. On day 5, these changes were less pronounced and sleep completely returned to the baseline by day 7. The EEG was suppressed in each frequency band and each vigilance state, and, in contrast to sleep, these changes in EEG persisted for 7 days. Brain temperature was decreased from day 3. These results suggest that NGF receptor-positive, cholinergic basal forebrain neurons are not necessary for the maintenance of total sleep time but contribute to the generation of normal EEG and the maintenance of brain temperature.

Effects of cholinergic depletion on evoked activity in the cortex of young and aged rats.

Degeneration of cholinergic neurons in the basal forebrain is a neural marker of Alzheimer's disease and is associated with perceptual and cognitive deficits. An idea that has attracted scientific scutiny is that aging makes the brain more susceptible to neurodegenerative diseases such as Alzheimer's. The purpose of this study was to compare the effects of the loss of cholinergic input from nucleus basalis of Meynert on evoked activity in the posteromedial barrel subfield of the somatosensory cortex in young (2-2.5 months) and aged (28-30 months) male Fisher hybrid rats. The mean firing rate and receptive fields of single neurons in the posteromedial barrel subfield of the somatosensory cortex were examined after selective lesions of cholinergic neurons in the nucleus basalis of Meynert with an immunotoxin. IgG 192-saporin. Functional properties of single neurons in young animals were affected much more significantly by cholinergic depletion than those in aged animals. In cholinergic-depleted young animals, the mean firing rate of evoked activity and receptive field of posteromedial barrel subfield neurons were significantly decreased. Cholinergic depletion caused a 14% decrease in evoked activity and a 33% increase in receptive field size in young animals. The mean firing rate and receptive field of single neurons were not affected by cholinergic depletion in aged animals. It is concluded that functional properties of cortical sensory neurons in young animals are more vulnerable to cholinergic depletion than are those of aged animals and that cholinergic depletion does not further impact the properties of neurons exposed to the processes of aging.