Acute response to cholinergic challenge predicts long‐term response to galantamine treatment in patients with Alzheimer's disease

Anne Catrien Baakman; Carmen Gavan; Lotte van Doeselaar; Marieke de Kam; Karen Broekhuizen; Ovidiu Bajenaru; Laura Camps; Eleonora L Swart; Kees Kalisvaart; Niki Schoonenboom; Evelien Lemstra; Philip Scheltens; Adam Cohen; Joop van Gerven; Geert Jan Groeneveld

doi:10.1111/bcp.15206

. 2022 Jan 26;88(6):2814–2829. doi: 10.1111/bcp.15206

Acute response to cholinergic challenge predicts long‐term response to galantamine treatment in patients with Alzheimer's disease

Anne Catrien Baakman ¹, Carmen Gavan ², Lotte van Doeselaar ¹, Marieke de Kam ¹, Karen Broekhuizen ¹, Ovidiu Bajenaru ², Laura Camps ¹, Eleonora L Swart ³, Kees Kalisvaart ⁴, Niki Schoonenboom ⁴, Evelien Lemstra ⁵, Philip Scheltens ⁵, Adam Cohen ¹, Joop van Gerven ¹, Geert Jan Groeneveld ^1,^6,^✉

PMCID: PMC9306507 PMID: 34964149

Abstract

Aims

Cholinesterase inhibitors (CEIs) have been shown to improve cognitive functioning in Alzheimer's disease (AD) patients, but are associated with multiple side effects and only 20–40% of the patients clinically improve. In this study, we aimed to investigate the acute pharmacodynamic (PD) effects of administration of a single dose of galantamine on central nervous system (CNS) functioning in mild to moderate AD patients and its potential to predict long‐term treatment response.

Methods

This study consisted of a challenge and treatment phase. In the challenge phase, a single dose of 16 mg galantamine was administered to 50 mild to moderate AD patients in a double‐blind, placebo‐controlled cross‐over fashion. Acute PD effects were monitored up to 5 hours after administration with use of the NeuroCart CNS test battery and safety and pharmacokinetics were assessed. In the treatment phase, patients were treated with open‐label galantamine according to regular clinical care. After 6 months of galantamine treatment, patients were categorized as either responder or as non‐responder based on their minimental state examination (MMSE), neuropsychiatric inventory (NPI) and disability assessment in dementia (DAD) scores. An analysis of covariance was performed to study the difference in acute PD effects during the challenge phase between responders and non‐responders.

Results

A single dose of galantamine significantly reduced saccadic reaction time (−0.0099; 95% CI = −0.0195, −0.0003; P = .0430), absolute frontal EEG parameters in alpha (−14.9; 95% CI = −21.0, −8.3; P = .0002), beta (−12.6; 95% CI = −19.4, −5.3; P = .0019) and theta (−17.9; 95% CI = −25.0, −10.0; P = .0001) frequencies. Relative frontal (−1.669; 95% CI = −2.999, −0.339; P = .0156) and occipital (−1.856; 95% CI = −3.339, −0.372; P = .0166) EEG power in theta frequency and relative occipital EEG power in the gamma frequency (1.316; 95% CI = 0.158, 2.475; P = .0273) also increased significantly compared to placebo. Acute decreases of absolute frontal alpha (−20.4; 95% CI = −31.6, −7.47; P = .0046), beta (−15.7; 95% CI = −28.3, −0.93; P = .0390) and theta (−25.9; 95% CI = −38.4, −10.9; P = .0024) EEG parameters and of relative frontal theta power (−3.27%; 95% CI = −5.96, −0.58; P = .0187) on EEG significantly distinguished responders (n = 11) from non‐responders (n = 32) after 6 months.

Conclusions

This study demonstrates that acute PD effects after single dose of galantamine are correlated with long‐term treatment effects and that patients who demonstrate a reduction in EEG power in the alpha and theta frequency after a single administration of galantamine 16 mg will most likely respond to treatment.

Keywords: Alzheimer's disease, cholinergic challenge, galantamine, pharmacology

What is already known about this subject

Cholinesterase inhibitors (CEIs) have been shown to improve cognitive functioning in Alzheimer's disease (AD) patients, but are associated with multiple side effects and only 20–40% of the patients clinically improve.
Thus, many patients are unnecessarily exposed to drug treatment and potentially experience adverse effects.
Conceptually, acute PD effects are expected to be correlated with treatment response if the clinical effect is related to the pharmacological activity of the compound.
A single administration of a CEI could be used in clinical practice to decide which patient to treat and which patient not to expose to unnecessary side effects.

What this study adds

Acute PD effects after a single dose of the CEI galantamine are correlated with long‐term treatment effects.
Patients who demonstrate a reduction in EEG power in the alpha and theta frequency after a single administration of galantamine 16 mg will most likely respond to treatment.

1. INTRODUCTION

Alzheimer's disease (AD) is the major cause of dementia worldwide. ¹ This neurodegenerative disorder is characterized by a profound loss of cholinergic innervation and cholinergic deficiency. ² , ³ , ⁴ As the disease progresses, cognitive functions deteriorate in parallel with loss of cholinergic neurons, which correlates with disease severity. ⁵ Despite huge efforts, no curative therapy has yet been found, and current therapies focus mainly on the loss of cholinergic function. Cholinesterase inhibitors (CEIs) fall under the class of cholinergic treatments currently in use for the symptomatic treatment of dementia. ⁶ , ⁷ , ⁸ CEIs attempt to restore the loss of acetylcholine occurring after the neurodegeneration of the cholinergic system by increasing the acetylcholine (ACh) levels in the synaptic cleft of the remaining cholinergic neurons. ⁶ , ⁷ , ⁸ Galantamine is an example of a specific, competitive and reversible CEI, which, however, may also have a more direct modulating effect on the nicotinic acetylcholine receptor (AChR). ⁶ CEIs have shown to improve cognitive function in AD, Lewy body dementia and Parkinson's disease dementia. ⁷ , ⁸

Unfortunately, CEIs lead to a clinical improvement in only 20–40% of the AD patients, depending on the definition of treatment response. ⁹ , ¹⁰ Since it is difficult to distinguish who will clinically improve in response to treatment and who will not at an early stage of disease, ¹⁰ , ¹¹ many patients are unnecessarily exposed to drug treatment and potentially experience adverse effects. It would be favourable to determine responsiveness to treatment before long‐term drug exposure. In daily clinical practice, a favourable response to CEI treatment is defined by the postponement of progression of symptoms of AD. This can only be determined at a point in time when clinical progression is expected. Usually, patients are treated for at least 6 months before treatment response is assessed, using clinical scales for cognitive domains, functioning in daily life and behaviour. However, based on the mechanism of action, CEIs are expected to increase the level of ACh in the synaptic cleft immediately after dosing. We argue that acute pharmacodynamic (PD) effects of CEIs can be measured when sensitive methods are used at multiple time‐points in the hours after dosing, especially in comparison to placebo in a cross‐over study design.

Acute PD effects of galantamine in AD patients have been reported previously, ¹² but only in pharmacological magnetic resonance imaging studies at one time‐point after dosing. ¹² , ¹³ , ¹⁴ One study showed an effect on paired associate learning after the administration of donepezil 5 mg; ¹⁵ however, this study had no placebo‐controlled cross‐over design and measurements were performed at one fixed time‐point after dosing. None of these studies reported a longer follow‐up period or associated correlation parameters. Other studies attempted to link long‐term treatment effects of rivastigmine to the pharmacokinetics (PK) in plasma and cerebrospinal fluid at steady state ¹⁶ or measured electroencephalography (EEG) changes after 1 week of treatment. ¹⁷ However, neither performed PD measurements in the first hours after single dosing. Conceptually, acute PD effects, when accurately measured, are expected to be correlated with treatment response, if the clinical effect is related to the pharmacological activity of the compound. By inference, a single administration of a CEI could be used in clinical practice to decide which patient to treat and which patient not to expose to unnecessary side effects.

Based on the pharmacological properties of CEIs and evidence from previous studies, we hypothesized that reactivity to an acute cholinergic challenge will predict the long‐term response to cholinergic treatment. ¹² , ¹⁷ In the present study, we therefore aimed to investigate the acute PK and PD effects of a single dose administration of galantamine on central nervous system (CNS) functioning in mild to moderate AD patients in a placebo‐controlled, cross‐over fashion. Galantamine was chosen for this purpose, rather than donepezil or rivastigmine, because at the time of study start, galantamine was the most used cholinesterase inhibitor for the treatment of patients with Alzheimer's disease in the Netherlands and as the second part of the study needed to correspond as much as possible to standard of care, we chose to do the challenge part with galantamine also. Subsequently, patients were treated with galantamine for 6 months and clinical response to treatment was evaluated. Finally, the relationship between the reactivity to the acute cholinergic challenge and clinical response to long‐term cholinergic treatment was assessed.

2. METHODS

2.1. Study design and subjects

This was a multicentre, double‐blind, placebo‐controlled, randomized cross‐over study with galantamine compared to placebo, followed by a 6 months open‐label treatment phase in patients with AD. Fifty patients with mild to moderate AD were included in the study. Inclusion was based on a clinical diagnosis of AD, Mini Mental State Examination (MMSE) score ranging from 18 to 26 and a Clinical Dementia Rating (CDR) ¹⁸ score between 0.5 and 2.0. Main exclusion criteria were the previous or current use of CEIs, anti‐cholinergic drugs or neuroleptics, contraindications for the use of CEIs, use of benzodiazepines 48 hours prior to the study days or any history of psychiatric disorders.

Before entering the study, all patients were screened for eligibility, including evaluation of diagnosis, use of medication, presence of contraindications for the use of galantamine, electrocardiogram (ECG) and laboratory investigations. Also, a training session for the pharmacodynamic measurements performed with the NeuroCart® CNS test battery was planned. This test battery includes 10 different computerized tasks and EEG on a wide range of CNS domains ¹⁹ , ²⁰ , ²¹ , ²² and is also sensitive to cholinergic effects. ²³ , ²⁴ All eligible patients entered the challenge phase, consisting of two study days, during which the effects of galantamine or placebo were measured according to a predefined time schedule, with a 1 week wash‐out period in between. Directly after the second challenge occasion, patients entered the open‐label treatment phase. During this phase, patients were treated with galantamine according to standard care for 6 months and visited the clinic after 2 months and 6 months of treatment for the assessment of clinical outcome measures. This study was performed in collaboration with the VU University Medical Center (Amsterdam, The Netherlands), and the University Hospital of Bucharest (Romania). Subjects were also recruited via the memory clinic of the Spaarne Gasthuis Hospital (Haarlem, The Netherlands). All subjects gave written informed consent for participation in the study. The study was approved by the Medical Ethics Committee of the VU University Medical Center and the Medical Ethics Committee of the Clinicii de neurologie a Spitalului Universitar de Urgenta and it was carried out according to ICH Good Clinical Practice. The PI who was overall responsible for the study was Geert Jan Groeneveld, MD, PhD. The local PI responsible in Romania was Ovidiu Bajenaru, MD, PhD.

2.2. Dosing rationale

2.2.1. Challenge phase

Previous studies have shown measurable changes in functional magnetic resonance imaging 3 hours post‐administration, and no serious side effects as a consequence of the administration of a single dose of 8 mg galantamine. ¹² , ¹³ , ¹⁴ Therefore, this study started with a challenge dose of 8 mg. An interim analysis was planned and performed when the first 11 patients completed the challenge phase to assess whether this dose induced any measurable acute PD effects compared to placebo. There were no significant differences in PD effects between galantamine 8 mg and placebo and side effects at this dose were minimal. A recently performed study by Klaassens and colleagues also found no PD effects after a single dose of galantamine 8 mg. ¹⁴ Based on this, it was decided to increase the challenge dose to 16 mg galantamine. Study drug was administered orally as one or two capsules, each containing 8 mg of galantamine hydrobromide or a placebo. During the challenge phase, an immediate release formulation of Reminyl® was used.

2.2.2. Treatment phase

Directly after completing the challenge phase, patients entered the treatment phase. Patients were treated with extended release galantamine (Reminyl® or equivalent) capsules, according to the guidelines used in daily clinical practice: to prevent side effects caused by fast accumulation due to the long half‐life of galantamine, the starting dose was 8 mg once daily for 4 weeks. The dose was then increased to 16 mg once daily for the remaining months.

2.3. Pharmacokinetic assessments

Venous blood samples were obtained via an indwelling catheter at baseline and at 0.25, 0.5, 1, 1.5, 2, 2.5, 3.5 and 5 hours following drug administration. Plasma galantamine concentrations were determined at the Department of Clinical Pharmacy and Pharmacology at the VU University Medical Centre by a validated method using high‐performance liquid chromatography coupled to tandem‐mass spectrometry.

2.4. Pharmacodynamic assessments

To evaluate the acute PD effects of galantamine, the NeuroCart® was used, including 10 different computerized tasks and EEG. The NeuroCart test battery has previously shown sensitivity to drug effects on a wide range of CNS domains ¹⁹ , ²⁰ , ²¹ , ²² and is also sensitive to (anti)cholinergic effects. ²³ , ²⁴ The N‐back tests evaluated working memory ²⁵ , ²⁶ , ²⁷ adaptive tracking measured sustained attention and eye‐hand coordination ²⁸ , ²⁹ , ³⁰ , ³¹ , ³² and the Simple Reaction Time task measured the attention and speed of information processing. ²⁹ The visual analogue scale according to Bond and Lader assessed changes in subjective states, ³³ the facial encoding and recognition task episodic memory, ¹² , ²¹ and the visual verbal learning test (VVLT) covered the scope of learning behaviour (i.e., acquisition, consolidation, storage and retrieval. ³⁰ Pharmaco‐electroencephalography, eye movements and pupil size were used to determine drug effects on neurophysiological and autonomous system function. ³⁰ , ³¹ , ³⁴ Pupil size, eye movements, adaptive tracking, simple reaction time, visual analogue scales and N‐back tests were performed twice at baseline, and at 1, 2, 4 and 5 hours following galantamine or placebo administration. The VVLT was executed 1.5 hours after drug administration (immediate recall) and 3.0 hours following drug administration (delayed recall and recognition). The facial recognition task was performed at baseline and 2.5 hours after dosage. Pharmaco‐EEG measurements were performed at baseline and 0.5, 1, 1,5, 2, 4 and 5 hours post galantamine administration. Measurements were performed in a quiet room with ambient illumination with only one subject per session in the same room.

2.5. Clinical outcome assessments

The Alzheimer's Disease Assessment (ADAS)‐cog subscale was used to evaluate the severity of cognitive and non‐cognitive behavioural dysfunction characteristic for AD patients. ³⁵ This subscale comprises 11 items that have been allocated to represent three key cognitive domains: language, memory and praxis. ³⁶ , ³⁷ , ³⁸ Positive changes on the ADAS‐cog scale (0–70) imply worsening of cognition. Cognitive performance of subjects was assessed by the Clinical Dementia Rating (CDR) scale, in which statements related to the following six domains are scored: memory, orientation, judgement and problem solving, community affairs, home and hobbies, and personal care. ¹⁸ The global CDR score is derived from a synthesis of the individual ratings in each domain in accordance with established clinical scoring rules and represents a 5‐point ordinal scale, where CDR 0 indicates no dementia, and CDR 0.5, 1, 2 and 3 indicate questionable, mild, moderate and severe dementia. The Disability Assessment in Dementia (DAD) scale was used to evaluate basic and instrumental activities of daily living (ADL). ³⁹ Items from this 46‐item questionnaire can be divided into basic ADL and instrumental ADL. Higher scores represent fewer disabilities and lower scores indicate increased disabilities. ⁴⁰ The Mini Mental State Examination (MMSE) is a brief 30‐point questionnaire test which was used to screen for cognitive impairment. ⁴¹ , ⁴² With the Neuropsychiatric Inventory (NPI), diverse behavioural and psychological symptoms of dementia were measured. ⁴³ The ADAS‐cog, CDR, DAD, MMSE and NPI were carried out after 2 and 6 months of treatment.

2.6. Safety assessments

Before participation in the study, all subjects underwent medical screening, including medical history, physical examination, vital signs measurements, 12‐lead ECG, urinalysis, urinary drug screen, haematology and biochemistry blood sampling. During study days, vital signs measurements, 12‐lead ECG, urinalysis, urinary drug screen, haematology and biochemistry blood sampling were performed at baseline. ECG and vital signs were additionally performed at 0.5, 1.5 and 5.0 hours after drug administration in order to monitor possible adverse effects of the drug and assess safety.

2.7. Statistics

2.7.1. Sample size calculation

The study aimed to enrol 50 patients with mild to moderate AD. This number was based on a sample size calculation that hypothesized an effect size comparable to the reduction in theta power on EEG examination (−27.3%) after onset of treatment with rivastigmine in patients who clinically improved that was observed in another study. ¹⁷ Of the 20 patients with mild to moderate AD who participated in that study, 8 (40%) clinically improved in response to treatment, defined as an improvement of short‐term memory after 6 months. A logistic regression analysis revealed that 50% of the observed variance in clinical improvement as a result of treatment could be explained by the decrease in theta power, 1 week after onset of treatment. ¹⁷ With an estimated correlation coefficient of r ² = 0.50, a sample size calculation determined that with an alpha of 0.05 and a power (1‐beta) of 0.8, at least 30 patients were needed to observe a significant correlation between the acute response to the galantamine challenge and clinical improvement after 26 weeks. With an estimated drop‐out rate of 35%, ¹¹ the total number of patients needed was calculated to be 46, which is why 50 patients were targeted.

2.7.2. Interim analysis

After the challenge phase, data of the first 11 subjects were collected and a predefined interim analysis was performed. For the interim analysis, the PD variables were analysed by mixed model of analysis with treatment, time and treatment by time as fixed factors, subject, subject by treatment and subject by time as random factors and the average pre‐value as covariate. The results were presented as a result table of the analysis with the P‐value of the contrast between placebo and galantamine, the least square means of the treatments, the estimate of the difference and the 95% confidence interval around the difference. No individual data were reported to avoid unblinding.

2.7.3. Pharmacodynamic analysis

Acute effects on different PD variables were analysed as described for the interim analysis. Log transformation was used to correct for log‐normal distribution of the data. Calculation of time and treatment by time effects were for graphical presentation purposes only; only contrasts within the overall treatment effect were estimated and reported, along with 95% confidence intervals. Log‐transformed parameters were back‐transformed after analysis where the results may be interpreted as percentage change. Due to the exploratory nature of this study, no formal adjustment for multiple testing was used.

2.7.4. Correlation analysis

To investigate whether the acute PD effects were correlated with the MMSE, NPI and DAD scores at 6 months independently, change from baseline AUC for galantamine and placebo were calculated and Pearson (or Spearman) correlation coefficients were calculated. According to Chan, correlation was defined as poor (0.1–0.2), fair (0.3–0.5), moderate (0.6–0.7), very strong (0.8–0.9) or perfect (1). ⁴⁴

The group of patients was subsequently divided into responders and non‐responders. If MMSE, NPI and DAD at month 6 were greater than or equal to MMSE, NPI and DAD at baseline, a patient was a responder. If not all three measurements improved or at least stayed the same, the patient was a non‐responder. The challenge effects of the PD variables were analysed comparing the responders with the non‐responders. The challenge variables were analysed with a mixed model analysis of variance with fixed factor group (responder/non‐responder), treatment, period, time, treatment by time, treatment by group and treatment by group by time as fixed factor, subject, subject by time and subject by treatment as random factor and the average pre‐value as covariate. The contrast of interest was responders (galantamine‐placebo) vs non‐responders (galantamine‐placebo). The difference in change from baseline galantamine AUC and the placebo AUC was graphically analysed for the responders and the non‐responders. The percentage of responders and non‐responders outside the range of the non‐responders and responders, respectively, was calculated.

2.7.5. Pharmacokinetic analysis

The following PK parameters were estimated using compartmental analysis: maximum plasma concentrations (C _max), time of maximum plasma concentrations (T _max), area under the concentration–time curve from time zero to the time of the last quantifiable concentration and to infinity (AUC_∞), terminal elimination rate constant (λz), terminal elimination half‐life (t _½), and clearance (CL/F).

2.8. Nomenclature of targets and ligands

Key protein targets and ligands in this article are hyperlinked to corresponding entries in http://www.guidetopharmacology.org, and are permanently archived in the Concise Guide to PHARMACOLOGY 2019/20. ⁴⁵ , ⁴⁶

3. RESULTS

In total, 50 patients with mild to moderate AD were included in our study. Of these patients, 39 were enrolled via the Centre for Human Drug Research and the VU Medical Center in the Netherlands (of whom five were recruited via the Spaarne Gasthuis in Haarlem) and 11 patients were enrolled at the Tangent data research unit at University Hospital of Bucharest in Romania. Patients had a mean age of 66.8 years (range 49–90) and a mean weight of 75.8 kg (range 50–122). The first 11 patients (all tested in The Netherlands) received 8 mg of galantamine. Following the predefined interim analysis, it was decided to escalate the dose to 16 mg of galantamine for the remaining 39 patients. Two patients prematurely dropped out of the study during the challenge phase due to practical issues (lack of time or hospitalization for unrelated reasons). Therefore, 48 patients could be analysed in the challenge phase of the study. During the treatment phase, three additional patients cancelled study appointments (one patient experienced side effects, two patients lacked time or were hospitalized for other reasons). Two patients had incomplete follow‐up data. A total of 43 patients could therefore be analysed in the treatment phase.

3.1. Challenge phase

3.1.1. Interim analysis

An interim analysis after the first 11 subjects revealed no clear differences between 8 mg galantamine treatment and placebo on most of the PD measurements. Differences were observed between galantamine and placebo treatment for the second immediate recall of the VVLT (−1.8; 95% CI = −2.7, −0.9; P = .0084). However, since no differences were found for all other parameters (see Supplementary Information), the measured PD effects of 8 mg galantamine were considered insufficient and it was decided to increase the dose of galantamine to 16 mg for the remaining 39 subjects. No interim analysis could be performed for the pupil size, N‐back average reaction time 2‐back and recognition of the VVLT, since too few subjects were able to perform these tests, due to the complexity of the computer interface. The computer interface was subsequently simplified based on this observation.

3.1.2. Pharmacodynamics

Acute PD effects of a single dose of galantamine in comparison to placebo in mild to moderate AD patients are displayed in Table 1. A single dose of galantamine significantly reduced saccadic reaction time (−0.0099; 95% CI = −0.0195, −0.0003; P = .0430) when compared to placebo condition. Peak effects on saccadic eye movements were observed around the T _max of galantamine. An improvement in performance on the adaptive tracker was observed after administration of galantamine, but the difference was not significant. Notably, galantamine appeared to increase performance on adaptive tracking at 1, 4 and 5 hours following drug administration, but not around 2 hours after administration.

TABLE 1.

Acute PD effects of a single dose of galantamine in mild to moderate AD patients

Parameter	LS means		LS means change from baseline		Contrasts
					Galantamine ‐ placebo
	Placebo	Galantamine	Placebo	Galantamine	Treatment P‐value	Treatment effect (95% CI)
Smooth pursuit (%)	27.9	28.1	−1.95	−1.78	0.16(−1.26, 1.59)	0.8147
Saccadic inaccuracy (%)	7.3	6.6	−0.27	−0.95	−0.69(−1.38, 0.01)	0.0516
Saccadic peak velocity (deg/s)	489.6	496.8	−12.28	−5.08	7.20(−4.62, 19.02)	0.2173
Saccadic reaction time (sec)	0.253	0.243	0.0061	−0.0038	−0.0099(−0.0195, −0.0003)	0.0430
Simple reaction time task (sec)	392.99	393.15	1.4%	1.5%	0.0%(−6.8%, 7.4%)	0.9911
Adaptive tracking (%)	17.76	18.54	0.084	0.863	0.779 (−0.247, 1.805)	0.1320
VAS alertness (mm)	61.5	56.7	−0.98	−5.83	−4.85 (−9.83, 0.13)	0.0560
VAS calmness (mm)	63.0	59.5	1.89	−1.62	−3.51 (−9.71, 2.70)	0.2541
VAS mood (mm)	64.4	62.5	0.17	−1.75	−1.92 (−6.37, 2.53)	0.3813
VAS nausea log (mm)	0.633	0.924	−0.0341	0.2567	0.2908 (0.0968, 0.4848)	0.0043
N‐back mean RT 0 back (msec)	512	524	5.7	17.9	12.2 (−21.6, 46.1)	0.4631
N‐back mean RT 1 back (msec)	651	627	−13.0	−37.1	−24.1 (−80.8, 32.5)	0.3754
N‐back mean RT 2 back (msec)	743	726	−26.6	−43.8	−17.2 (−102.9, 68.4)	0.6797
N‐back corr‐incorr/total 0	5.93	5.97	−0.054	−0.007	0.047 (−0.070, 0.163)	0.4081
N‐back corr‐incorr/total 1	5.28	5.33	0.202	0.248	0.046 (−0.357, 0.448)	0.8158
N‐back corr‐incorr/total 2	3.43	3.37	−0.449	−0.513	−0.064(−0.584, 0.456)	0.8014
EEG alpha Fz‐Cz (uV)	2.17	1.86	10.8%	−5.3%	−14.9% (−21.0%, −8.3%)	0.0002
EEG alpha Pz‐Oz (uV)	3.26	3.22	−0.7%	−2.0%	−1.3% (−10.8%, 9.2%)	0.7953
EEG beta Fz‐Cz (uV)	1.88	1.66	10.2%	−3.0%	−12,0% (−18,7%, −4,7%)	0.0026
EEG beta Pz‐Oz (uV)	1.87	1.92	1.2%	3.9%	2.6% (−6.0%, 12.0%)	0.5505
EEG delta Fz‐Cz (uV)	1.48	1.35	12.5%	2.9%	−8,3% (−19,9%, 4.9%)	0.2033
EEG delta Pz‐Oz (uV)	1.60	1.49	2.2%	−4.6%	−6.7% (−18.6%, 7.0%)	0.3111
EEG gamma Fz‐Cz (uV)	0.56	0.53	7.7%	2.2%	−5,10% (−13,8%, 4,5%)	0.2763
EEG gamma Pz‐Oz (uV)	0.63	0.72	−1.4%	12.3%	14.0% (−2.3%, 33.0%)	0.0923
EEG theta Fz‐Cz (uV)	2.03	1.67	16,9%	−3,9%	−17.9% (−25.0%, −10,1%)	0.0001
EEG theta Pz‐Oz (uV)	2.26	2.05	2.2%	−7.5%	−9.5% (−20.9%, 3.5%)	0.1403
EEG relative alpha Fz‐Cz (%)	26.48	25.93	−0,398	−0.950	−0,552 (−1497, 0,393)	0.2427
EEG relative alpha Pz‐Oz (%)	33.43	33.87	−0,745	−0.307	0.438 (−1.442, 2.318)	0.6330
EEG relative beta Fz‐Cz (%)	23.12	23.01	−0,447	−0.552	−0.106 (−0.814, 0.603)	0.7628
EEG relative beta Pz‐Oz (%)	19.09	19.9	−0,082	0.727	0.809 (−0.162, 1.781)	0.0990
EEG relative delta Fz‐Cz (%)	18.26	19.5	0,121	1.359	1238 (−0.347, 2.823)	0.1213
EEG relative delta Pz‐Oz (%)	17.09	16.21	0,717	−0.168	−0.885 (−2.207, 0.437)	0.1811
EEG relative gamma Fz‐Cz (%)	7.22	8.08	−0,225	0.643	0.868 (−0.018, 1.753)	0.0544
EEG relative gamma Pz‐Oz (%)	7.04	8.35	−0,226	1.091	1.316 (0.158, 2.475)	0.0273
EEG relative theta Fz‐Cz (%)	25.07	23.4	1098	−0.571	−1.669 (−2.999, −0.339)	0.0156
EEG relative theta Pz‐Oz (%)	23.54	21.68	0,524	−1.332	−1.856 (−3.339, −0.372)	0.0166
Left pupil/iris ratio	0.3486	0.3537	−0.01204	−0.00690	0.00513 (−0.01380, 0.02406)	0.5846
Right pupil/iris ratio	0.3485	0.3557	−0.00350	0.00367	0.00717 (−0.01071, 0.02506)	0.4219
Face: Number correct	14.8	14.7	−0.46	−0.60	−0.14 (−1.68, 1.39)	0.8506
Face: Avg RT correct (msec)	1807	1733	117.6	44.2	−73.4 (−332.9, 186.1)	0.5574
Word recall 1 correct	2.4	2.5			0.14 (−0.31, 0.60)	0.5242
Word recall 2 correct	4.1	4.1			−0.00 (−0.68, 0.67)	0.9946
Word recall 3 correct	4.7	5.0			0.30 (−0.46, 1.05)	0.4319
Delayed word recall correct	0.9	0.7			−0.21 (−0.63, 0.21)	0.3138
Delayed word recognition correct	11.2	10.4			−0.89 (−2.72, 0.94)	0.3301
Delayed word recog RT correct (msec)	5285.3	4111.3			−1174.07 (−2602.93, 254.80)	0.1038
IGF_BP3 serum (mg/L)	2.54	2.62	1.1%	4.6%	3.5% (−1.0%, 8.2%)	0.1297
IGF_I serum (nmol/L)	19.06	19.42	2.2%	4.1%	1.9% (−1.4%, 5.2%)	0.2502

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In addition, galantamine administration acutely reduced absolute alpha (−14.9; 95% CI = −21.0, −8.3; P = .0002), beta (−12.6; 95% CI = −19.4, −5.3; P = .0019) and theta power (−17.9; 95% CI = −25.0, −10.0; P = .0001) and relative frontal (−1.669; 95% CI = −2.999, −0.339; P = .0156) and occipital (−1.856; 95% CI = −3.339, −0.372; P = .0166) EEG power in theta frequency and increased relative occipital EEG power in the gamma frequency (1.316; 95% CI = 0.158, 2.475; P = .0273) on the pharmaco‐electroencephalography in comparison to placebo. For all EEG spectra, except for the delta range, a significant decrease in power was observed compared to placebo, with strongest reductions around the T _max of galantamine. For the delta range, a reduction of absolute power was observed following galantamine administration, but the difference was not significant. Reductions in delta power were strongest around 2 hours following drug administration and continued to be equally reduced over time. VAS scores on nausea significantly increased after galantamine administration compared to placebo (0.2908 log mm; 95% CI = 0.0968, 0.4848; P = .0043). All other PD parameters were not significantly affected by galantamine.

3.1.3. Pharmacokinetics

Mean T _max was 2.42 h (range 1.00–4.58) for 8 mg and 1.38 h (range 0.45–4.60) for 16 mg of galantamine with a C _max of respectively 43.17 ng mL⁻¹ (range 23.90–57.30) and 79.00 (range 43.30–139.00). Graphs and other PK parameters can be found in the Supporting Information.

3.2. Treatment phase

After 6 months, 11 (26%) patients were defined as responders to galantamine treatment and 32 (74%) patients were defined as non‐responders, based on the a priori definition of response of no decline on MMSE, DAD and NPI. Table 2 describes the differences between responders and non‐responders in their reactivity to the acute cholinergic challenge compared to placebo. These differences were statistically significant for absolute frontal alpha (−20.4; 95% CI = −31.6, −7.47; P = .0046), beta (−15.7; 95% CI = −28.3, −0.93; P = .0390) and theta power (−25.9; 95% CI = −38.4, −10.9; P = .0024) and for relative frontal theta power (−3.27%; 95% CI = −5.96, −0.58; P = .0187) on EEG. It is interesting to note that on visual inspection, long‐term responders showed an acute increase after placebo on absolute frontal EEG parameters and on relative frontal theta power compared to baseline on the placebo occasion and a decrease compared to baseline on the galantamine occasion, whereas non‐responders hardly showed any change from baseline on either the placebo or galantamine occasion (see Figure 1). On the scatter plots, both absolute frontal alpha and frontal theta power distinguished responders from non‐responders well, with minimal overlap between responders and non‐responders (see Figure 2). For frontal alpha power, no responders were in the overlapping range. For frontal theta power, two responders (22.2%) and three non‐responders (12.5%) were in the overlapping range. For relative frontal theta power on the EEG, four responders (80%) and nine non‐responders (64.3%) were in the overlapping range. Acute improvements in saccadic eye movements that were observed after single dose galantamine did not clearly predict long‐term clinical improvement: saccadic peak velocity increased on average in responders but not in non‐responders, but this failed to reach statistical significance (Table 2).

TABLE 2.

Differences between responders and non‐responders in their reactivity to the cholinergic challenge compared to placebo

Parameter	LS means		Contrast
	Responders (gal‐Plac)	Non‐responders (gal‐Plac)	Responders (gal‐Plac) vs non‐responders (gal‐Plac)
	Responders (gal‐Plac)	Non‐responders (gal‐Plac)	Treatment effect (95% CI)	P‐value
Smooth pursuit (%)	0.80	−0.40	1.21 (−1.63, 4.05)	0.3882
Saccadic inaccuracy (%)	−0.90	−0.50	−0.43 (−1.80, 0.94)	0.5218
Saccadic peak velocity (deg/s)	18.20	−3.80	22.09 (−1.38, 45.57)	0.0636
Saccadic reaction time (sec)	−0.008	−0.012	0.0043 (−0.01, 0.02)	0.6498
Simple reaction time task (sec)	1.04%	0.96%	7.80% (−6.40%, 24.10%)	0.2841
Adaptive tracking (%)	0.71	0.85	−0.14 (−2.19, 1.92)	0.8948
VAS alertness (mm)	−6.50	−3.20	−3.35 (−13.31, 6.61)	0.4968
VAS calmness (mm)	−2.80	−4.20	1.43 (−10.9, 13.85)	0.8135
VAS mood (mm)	−2.90	−0.90	−2.03 (−10.87, 6.82)	0.6398
VAS nausea log (mm)	0.20	0.379	−0,17 (−0.56, 0.21)	0.3595
N‐back mean RT 0 back (msec)	9	15	−6.10 (−73.40, 61.10)	0.8518
N‐back mean RT 1 back (msec)	−21	−27	5.40 (−106.80, 117.60)	0.9187
N‐back mean RT 2 back (msec)	0	−34	33.60 (−142.30, 209.50)	0.6948
N‐back corr‐incorr/total 0	−0.05	0.14	−0.19 (−0.42, 0.04)	0.1028
N‐back corr‐incorr/total 1	−0.11	0.21	−0.32 (−1.12, 0.48)	0.4126
N‐back corr‐incorr/total 2	0.00	−0.13	0.14 (−0.90, 1.17)	0.7873
EEG alpha Fz‐Cz (uV)	0.77%	0.95%	−18.4% (−29.6%, −5.5%)	0.0086
EEG alpha Pz‐Oz (uV)	0.93%	1.05%	−11.2% (−27.5%, 8.9%)	0.2440
EEG beta Fz‐Cz (uV)	0.82%	0.95%	−14.0% (−26.6%, 0.9%)	0.0629
EEG beta Pz‐Oz (uV)	0.99%	1.07%	−7.7% (−22.6%, 10.1%)	0.3605
EEG delta Fz‐Cz (uV)	0.86%	0.98%	−11.6% (−32.8%, 16.2%)	0.3644
EEG delta Pz‐Oz (uV)	0.91%	0.96%	−5.3% (−28.0%, 24.6%)	0.6889
EEG gamma Fz‐Cz (uV)	0.93%	0.97%	−3.7% (−20.7%, 16.9%)	0.6924
EEG gamma Pz‐Oz (uV)	1.13%	1.15%	−2.0% (−28.1%, 33.7%)	0.8970
EEG theta Fz‐Cz (uV)	0.71%	0.95%	−25.3% (−37.8%, −10.4%)	0.0027
EEG theta Pz‐Oz (uV)	0.81%	1.02%	−20.7% (−39.5%, 4.0%)	0.0903
EEG relative alpha Fz‐Cz (%)	−0.82	−0.28	−0.538 (−2.441, 1.364)	0.5679
EEG relative alpha Pz‐Oz (%)	0.73	0.14	0.590 (−3.184, 4.365)	0.7481
EEG relative beta Fz‐Cz (%)	0.04	−0.25	0.282 (−1.147, 1.711)	0.6898
EEG relative beta Pz‐Oz (%)	1.19	0.43	0.767 (−1.178, 2.711)	0.4258
EEG relative delta Fz‐Cz (%)	2.06	0.42	1.644 (−1.556, 4.845)	0.3029
EEG relative delta Pz‐Oz (%)	−0.50	−1.27	0.771 (−1.874, 3.415)	0.5548
EEG relative gamma Fz‐Cz (%)	1.54	0.20	1.341 (−0.456, 3.137)	0.1375
EEG relative gamma Pz‐Oz (%)	1.60	1.04	0.561 (−1765, 2.886)	0.6256
EEG relative theta Fz‐Cz (%)	−3.30	−0.03	−3.271 (−5.958, −0.584)	0.0187
EEG relative theta Pz‐Oz (%)	−3.18	−0.53	−2.651 (−5.631, 0.328)	0.0785
Left pupil/iris ratio	0.0037	0.0065	−0.00282 (−0.04087, 0.03524)	0.8811
Right pupil/iris ratio	0.0083	0.0060	0.00232 (−0.03353, 0.03817)	0.8966
Face: Number correct	−1.1	0.8	−1.86 (−4.90, 1.19)	0.2226
Face: Avg RT correct (msec)	−72	−75	2.3 (−513.3, 518.0)	0.9924
Word recall 1 correct	0.1	0.2	−0.06 (−0.97, 0.85)	0.8962
Word recall 2 correct	−0.7	0.7	−1.34 (−2.68, 0.01)	0.0517
Word recall 3 correct	0.3	0.3	−0.08 (−1.59, 1.43)	0.9129
Delayed word recall correct	−0.3	−0.1	−0.21 (−1.05, 0.62)	0.6072
Delayed word recognition correct	−0.7	−1.1	0.41 (−3.23, 4.05)	0.8207
Delayed word recog RT correct (msec)	−1885.8	−462.4	−1423.38 (−4257.69, 1410.93)	0.3135
IGF_BP3 serum (mg/L)	1.04%	1.03%	1.0% (−7.6%, 10.4%)	0.8265
IGF_I serum (nmol/L)	1.01%	1.03%	−1.8% (−8.0%, 4.8%)	0.5649

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PD variables were analysed by mixed model of analysis with treatment, time and treatment by time as fixed factors, subject, subject by treatment and subject by time as random factors, and the average pre‐value as covariate. Subjects were responders if MMSE, NPI and DAD at 6 months ≥ MMSE, NPI and DAD at baseline.

Changes in relative frontal EEG alpha and theta parameters of responders and non‐responders. This figure shows the changes in relative frontal EEG alpha (A) and theta (B) parameters of responders and non‐responders compared to baseline on either the placebo or galantamine occasion. Long‐term responders show an acute increase after placebo on absolute frontal EEG parameters and on relative frontal theta power compared to baseline on the placebo occasion and a decrease compared to baseline on the galantamine occasion, whereas non‐responders hardly show any change from baseline on either the placebo or galantamine occasion

Delta AUC in relative frontal EEG alpha and theta parameters of responders and non‐responders. This figure shows a plot of delta AUC in relative frontal EEG alpha (A) and theta (B) power parameters of responders and non‐responders. On the scatter plots, both absolute frontal alpha and frontal theta power distinguish responders from non‐responders, with minimal overlap between responders and non‐responders. For frontal alpha power, no responders are in the overlapping range. For frontal theta power, two responders (22.2%) and three non‐responders (12.5%) are in the overlapping range

Correlations between the acute PD effects and MMSE, NPI and DAD scores at 6 months independently, are shown in the Supporting Information. Table S2 shows that the majority of the coefficients of correlation reached a value under (−)0.50, which can be considered as fair. ⁴⁴ Coefficients reaching levels over (−)0.50 showed a moderate correlation between acute effects on smooth pursuit (r = 0.58), alertness (r = 0.54), N‐back (r = 0.63) and relative frontal alpha power on EEG (r = −0.59) and treatment response according to the DAD only.

3.3. Safety

Of all patients in the challenge phase, 39 reported at least one treatment emergent adverse event. Nausea was the most frequent reported adverse event, with six (54.5%) patients receiving 8 mg and 25 (64.1%) patients receiving 16 mg of galantamine and two (4%) patients receiving placebo. Diarrhoea was reported in five (12.8%) patients on galantamine 16 mg and one (2.6%) patient on placebo. Vomiting was reported in two (18.2%) patients on galantamine 8 mg and 14 (35.9%) patients on galantamine 16 mg. Dizziness was reported in two (18.2%) patients on galantamine 8 mg, 15 (38.5%) patients on galantamine 16 mg and two (4%) patients on placebo. Malaise and somnolence were reported in four (10.3%) patients on galantamine 16 mg and one (2.6%) patient on placebo. None of the other reported AEs occurred in more than 10% of patients. All adverse events were considered mild or moderate and spontaneously disappeared after a few hours.

During the treatment phase, one patient experienced moderate nausea during the first week of treatment and decided to discontinue the study and stop using galantamine. Two patients experienced mild nausea in the first 2 months of treatment. This subsided spontaneously and patients continued the use of galantamine. One patient reported moderate hyperhidrosis at the 6 month visit. In hindsight, this had been present the whole period. This patient decided to stop using galantamine.

4. DISCUSSION

In this study, we investigated the acute pharmacodynamic effects of a single dose administration of galantamine on CNS functioning in mild to moderate AD patients and its role as a potential predictor of long‐term treatment response. The results show improvements of saccadic eye movements and reductions of frontal EEG parameters in alpha, beta and theta frequencies after the challenge phase. Acute decreases of absolute frontal alpha, beta and theta power on EEG and an acute decrease in relative theta power significantly correlated with long‐term response to galantamine treatment. In addition, a highly significant effect on the nausea VAS score was found, which may have particularly had an impact on tests that required sustained attention or active participation.

Reductions in saccadic inaccuracy and reaction time during the challenge phase might reflect an improvement in visual attentional function. ⁴⁵ The cholinergic neuronal system plays a well‐known role in the maintenance of attention through projections of neurons in the basal forebrain complex to broad areas of the neocortex. Moreover, slowing of saccadic eye movements is considered a biomarker of declining alertness, particularly caused by benzodiazepines, ⁴⁶ , ⁴⁷ , ⁴⁸ , ⁴⁹ , ⁵⁰ and eye movements are also sensitive to anticholinergic drugs. In this context it is interesting to note that patients demonstrated a clear and anticipated improvement in attentional function, without a statistically significant improvement in mean adaptive tracker performance. The adaptive tracker is known for its sensitivity to disturbances and enhancement of central cholinergic neuronal functioning and can be regarded as a test of sustained attention. ²¹ , ²³ , ⁴⁷ It might be that a reduced eye‐hand coordination in this population of elderly patients has played a role in this discrepancy. The occurrence of adverse events (e.g., nausea) during the challenge phase of the study, as well as the highly significant effect on the nausea VAS score may also have played a role in obscuring some of the beneficial effects of galantamine on CNS test performance, as some patients were not able to perform all tests, and particularly the adaptive tracking test which requires sustained attention.

In addition to the acute improvement in attentional function, the results show decreases of frontal alpha, beta and theta EEG parameters after dosing in the challenge phase. Slow wave activity, such as theta and delta waves, are associated with a lower cognitive function in AD patients. ⁵¹ , ⁵² Previous studies have already reported reductions in theta power following chronic CEI treatment. ¹⁷ , ⁵³ In this study we demonstrate that galantamine administration also acutely reduces theta power in AD patients. Previously, an increase in frontal theta power was observed in a condition of mental exhaustion. ⁵⁴ This might explain the observed increase in theta power during the day on the placebo occasion among patients classified as responders. This might also explain the increase of theta power in responders after the administration of placebo in the challenge phase. Interestingly, our results indicate that a single dose of galantamine is already able to reduce theta power. It is surprising that galantamine administration also reduced alpha and beta power in our study, while faster wavelengths are associated with improved cognition. ⁵¹ , ⁵² , ⁵⁵ , ⁵⁶ However, the absolute values for alpha and beta power reduction were relatively small and there was no reduction in relative alpha or beta power. Also, studies involving the anti‐cholinergic and cognitive impairing drug scopolamine have reported conflicting results regarding the effects on alpha and beta power. ²¹ , ⁵⁷

Overall, there is a serious need for predictive markers of treatment response following CEI treatment in AD patients. So far it has been impossible to predict who will respond to CEI treatment and only 20–40% of the patients clinically improve. Most of the attempts to predict clinical response to long‐term treatment included pre‐dose characteristics, for example sex, ⁵⁸ , ⁵⁹ , ⁶⁰ , ⁶¹ age, ⁶² , ⁶³ severity of cognitive impairment and impaired performance on baseline neuropsychological test scores at baseline, ¹¹ , ⁶⁴ , ⁶⁵ , ⁶⁶ , ⁶⁷ pre‐treatment progression rate, ⁶⁸ , ⁶⁹ , ⁷⁰ , ⁷¹ cerebrospinal fluid levels of Aβ42, T‐tau and P‐tau at baseline, ⁶⁸ , ⁷² carotid intima media thickness, ⁷³ regional cerebral blood flow of the lateral and medial frontal lobes, ⁷⁴ substantia innominata atrophy, ⁷⁵ , ⁷⁶ performance on baseline alertness tests, ⁹ baseline behavioural ⁷⁷ and SPECT profile, ⁷⁸ pre‐treatment blood pressure drop, ⁶² , ⁷⁹ and APOE genotype. ⁵⁸ , ⁵⁹ , ⁶⁰ , ⁶¹ , ⁸⁰ , ⁸¹ , ⁸² , ⁸³ Some of these factors showed a positive correlation with treatment response. Our findings suggest that patients demonstrating a reduction in EEG alpha and theta power and saccadic eye movements after a single administration of galantamine 16 mg are more likely to respond to treatment. Nevertheless, it remains to be investigated how the addition of a galantamine challenge adds value on top of the above‐mentioned correlations found in previous studies in predicting treatment response.

Lanctôt and colleagues reviewed studies focusing on methods to predict the response to anticholinesterase therapy and markers for treatment response. ⁸⁴ They were able to demonstrate the predictive value of qEEG profile after a test dose of the CEI tacrine, based on four clinical trials. Alhainen et al. firstly demonstrated that an increased alpha‐theta ratio 90 minutes after a 50 mg test dose of tacrine led to higher MMSE scores 4 weeks post‐treatment in 14 patients with probable AD. ⁸⁵ Alhainen and Riekkinen confirmed these findings over a longer term and showed that responders after 7 weeks demonstrated a significant increase in mean absolute alpha power and alpha/theta ratio 90 minutes after a 50 mg test dose of tacrine. ⁸⁶ Knott et al. observed an increase of relative alpha and delta power waves in responders at 12 weeks, only 2 hours after an oral dose of 30 mg tacrine. ⁸⁷ Almkvist et al. suggested the validity of baseline EEG profiles as predictors of response to CEI therapy in 24 mildly to very mildly demented AD patients. ⁸⁸ Except for the trial by Almkvist et al., these trials had an open‐label design and all of them included only small numbers of patients, thus replication of these findings under double‐blind conditions with larger patient samples was in our view necessary before conclusions can be drawn. Adler et al. further showed that treatment with rivastigmine 3 mg/day for 1 week led to a significant decrease in theta power on EEG which significantly correlated with responder status. When theta power and a baseline score for short‐term memory were both included as independent variables in a logistic regression model, treatment response could be accurately predicted. ¹⁷ Interestingly, the decrease in absolute alpha and theta power on EEG also predicted treatment response in our study. If we had selected patients to be treated with galantamine based on either absolute frontal alpha power or absolute frontal theta power, and also had treated patients in the overlapping range, all patients defined as treatment responders would receive treatment. If this selection were based on absolute alpha power, no non‐responders would be treated. A selection based on absolute frontal theta power would result in the treatment of three non‐responders. When selecting based on relative frontal theta power, nine non‐responders would be treated. Several combinations of these parameters have been investigated, but do not lead to a better prediction of treatment response. Moreover, all these explorations were post hoc and they would obviously require prospective validation.

While the studies of Adler, the Lanctôt trials and our study show some inconsistencies, i.e. none of the other studies investigated the effects of galantamine and all of them used different definitions of “acute response” (ranging from 90 minutes to 1 week), the predictive role of theta power on EEG seems consistent and is also confirmed in the current study. The Lanctôt trials interestingly report on the increased alpha/theta ratio as a discriminator between responders and non‐responders, and not on absolute power EEG bands. Previous studies have shown that high/low band frequency ratios—e.g., alpha/theta ratios—can easily differentiate between AD patients and controls. ⁸⁹ , ⁹⁰ , ⁹¹ In our study, alpha/theta ratio was not a predefined outcome measure.

The sizeable group, the placebo‐controlled cross‐over design and frequently repeated measures after dosing in the challenge phase and the combination with a follow‐up study are strong aspects of the current study. Although the predefined response criteria of improvement on all three clinical scales may seem strict, this definition is based on not only improvement in cognition, but also activities of daily living and behavioural aspects, and it is closer, therefore, to a true clinical improvement than a responder criterion based on only one of these tests. If a patient declines in one dimension, e.g. ADL functioning, but not in another, e.g. cognitive functioning, both patient and doctor are likely to still regard this as an unsatisfactory non‐response to treatment. Also, the correlations between the individual challenge tests and clinical follow‐up measures did not show any consistent correlations and the number of responders (11 [25%]), which was consistent with expectations based on previous studies. ¹⁰ , ¹⁷ , ⁸³ The difference between responders and non‐responders could not be attributed to differences in levels of drug exposure, since there was no difference in average plasma concentrations of galantamine after 2 months of treatment between responders and non‐responders.

It should be noted that sample size calculations were based on the observed variance in clinical improvement correlated with the decrease in theta power in a comparable study, ¹⁷ while we mainly draw conclusions about dichotomized treatment response (responder and non‐responder) at 6 months in relation with acute challenge effects of PD variables. As data from that study were most comparable to data in the current study at that time, we believe this as the most appropriate method. Also, a responder score based on MMSE, NPI and DAD, instead of independent scores, seemed more representative for real‐world clinical improvement in AD patients. Other weaknesses of this study include the occurrence of side effects due to a pharmacological challenge, which were such that in the challenge phase some patients were not able to perform all tests due to nausea or had to decline the last round of tests due to fatigue. Also, especially the 2‐back condition of the N‐back turned out to be too difficult for AD patients.

This study is the first placebo‐controlled study with cross‐over design that links typical PD effects in an early phase clinical drug trial to the clinically relevant outcome measures used for phase III registration studies in the field of AD. Furthermore, this study generates a well‐defined time‐profile of the effects of galantamine in the target population of patients with mild to moderate AD, with an observed T _max of galantamine around 2 hours after administration, which is consistent with previously reported findings of a T _max of approximately 1.5 hours after a single oral dose of 10 mg galantamine with immediate release formulation. ⁹² Reductions in both absolute and relative theta power were obviously most pronounced around 2 hours after the administration of galantamine and continued to be equally reduced over time. Cut‐off criteria seem arbitrary; however, we believe that cut‐off criteria based on multiple tests are more representative of the actual patient condition, compared to cut‐off criteria based on one test.

5. CONCLUSION

This study demonstrates that acute PD effects after a single dose of galantamine are correlated with long‐term treatment effects and that patients demonstrating a reduction in EEG alpha and theta power and saccadic eye movements after a single administration of galantamine 16 mg are more likely to respond to treatment. Further confirmation of these findings is needed from prospective trials. This study takes a first step towards finding predictive biomarkers of treatment response to CEIs. In the future, these biomarkers might prevent the redundant exposure of AD patients to drug treatment and its related side effects.

COMPETING INTERESTS

The authors declare that they have no competing interests.

CONTRIBUTORS

A.B., M.K., K.B., E.S., E.L., P.S., A.C., J.G. and G.G. contributed to the design of the study and writing of the study protocol. A.B., C.G., N.S., O.B. and G.G. were involved in recruitment of patients and clinical study execution. M.K. performed the statistical analyses. All authors contributed substantially to the interpretation of data and drafting of the manuscript. All authors read and approved the final manuscript.

Supporting information

Table S1 Acute PD effects of a single dose of galantamine in comparison to placebo, based on the pre‐defined interim analysis of the first 11 subjects

Table S2: Pearson correlations of change from baseline AUC in the galantamine and placebo groups with delta DAD, MMSE, NPI and ADAS scores at 6 months

Table S3: Pharmacokinetic parameters of galantamine 16 and 8 mg

Figure S1 Changes in relative frontal EEG beta parameters of responders and non‐responders compared to baseline on either the placebo or galantamine occasion

Figure S2. Plot of delta AUC in relative frontal EEG beta power parameters by responder/non‐responder

Figure S3. Galantamine 16 and 8 mg concentration–time plots

Click here for additional data file.^{(332.5KB, docx)}

ACKNOWLEDGEMENTS

We would like to express great appreciation to the neurologists and geriatricians at the memory clinic in the Spaarne Gasthuis (Haarlem, the Netherlands) and to Ilan Gonen and colleagues of Tangent Data (Bucharest, Romania) for their help in selecting patients. Special thanks are offered to all patients who participated in the study. We are particularly grateful for the grant offered by ZonMW for funding of this study. We are thankful for the constructive comments provided by the two referees. This study was partly funded by ZonMW in the priority medicine programme with dossier number 113102001. ZonMW was not involved in any aspects of study design, data collection, analysis, interpretation or manuscript writing. This study was funded by Dutch national subsidy provider ZonMW, programme "Goed Gebruik Geneesmiddelen" (sub‐programme: PMO), project number 113102001.

Baakman AC, Gavan C, van Doeselaar L, et al. Acute response to cholinergic challenge predicts long‐term response to galantamine treatment in patients with Alzheimer's disease. Br J Clin Pharmacol. 2022;88(6):2814-2829. doi: 10.1111/bcp.15206

The authors confirm that the Principal Investigator for this paper is Prof. Geert Jan Groeneveld and that he had direct clinical responsibility for patients.

Trial registration: ISRCTN, ISRCTN82825745. Registered 21 August 2019, Retrospectively registered, http://www.isrctn.com/ISRCTN82825745

Funding information ZonMW, Grant/Award Number: 113102001

DATA AVAILABILITY STATEMENT

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Table S1 Acute PD effects of a single dose of galantamine in comparison to placebo, based on the pre‐defined interim analysis of the first 11 subjects

Table S2: Pearson correlations of change from baseline AUC in the galantamine and placebo groups with delta DAD, MMSE, NPI and ADAS scores at 6 months

Table S3: Pharmacokinetic parameters of galantamine 16 and 8 mg

Figure S1 Changes in relative frontal EEG beta parameters of responders and non‐responders compared to baseline on either the placebo or galantamine occasion

Figure S2. Plot of delta AUC in relative frontal EEG beta power parameters by responder/non‐responder

Figure S3. Galantamine 16 and 8 mg concentration–time plots

Click here for additional data file.^{(332.5KB, docx)}

Data Availability Statement

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

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PERMALINK

Acute response to cholinergic challenge predicts long‐term response to galantamine treatment in patients with Alzheimer's disease

Anne Catrien Baakman

Carmen Gavan

Lotte van Doeselaar

Marieke de Kam

Karen Broekhuizen

Ovidiu Bajenaru

Laura Camps

Eleonora L Swart

Kees Kalisvaart

Niki Schoonenboom

Evelien Lemstra

Philip Scheltens

Adam Cohen

Joop van Gerven

Geert Jan Groeneveld

Abstract

Aims

Methods

Results

Conclusions

What is already known about this subject

What this study adds

1. INTRODUCTION

2. METHODS

2.1. Study design and subjects

2.2. Dosing rationale

2.2.1. Challenge phase

2.2.2. Treatment phase

2.3. Pharmacokinetic assessments

2.4. Pharmacodynamic assessments

2.5. Clinical outcome assessments

2.6. Safety assessments

2.7. Statistics

2.7.1. Sample size calculation

2.7.2. Interim analysis

2.7.3. Pharmacodynamic analysis

2.7.4. Correlation analysis

2.7.5. Pharmacokinetic analysis

2.8. Nomenclature of targets and ligands

3. RESULTS

3.1. Challenge phase

3.1.1. Interim analysis

3.1.2. Pharmacodynamics

TABLE 1.

3.1.3. Pharmacokinetics

3.2. Treatment phase

TABLE 2.

FIGURE 1.

FIGURE 2.

3.3. Safety

4. DISCUSSION

5. CONCLUSION

COMPETING INTERESTS

CONTRIBUTORS

Supporting information

ACKNOWLEDGEMENTS

DATA AVAILABILITY STATEMENT

REFERENCES

Associated Data

Supplementary Materials

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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