Parkinson’s disease in the state of Michoacan, evolution, and treatment

García-Villa, Marcela; Leal-Cantú, Raúl; Madrigal-Salas, Rosa G.; Rodríguez-Leyva, Ildefonso; Quintana-Díaz, Mariana A.; Gonzalez-García, Conne L.; García-Villa, Marcela; Leal-Cantú, Raúl; Madrigal-Salas, Rosa G.; Rodríguez-Leyva, Ildefonso; Quintana-Díaz, Mariana A.; Gonzalez-García, Conne L.

doi:10.24875/rmn.21000018

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Revista mexicana de neurociencia

versión On-line ISSN 2604-6180versión impresa ISSN 1665-5044

Rev. mex. neurocienc. vol.23 no.1 Ciudad de México ene./feb. 2022 Epub 28-Feb-2022

https://doi.org/10.24875/rmn.21000018

Original articles

Parkinson’s disease in the state of Michoacan, evolution, and treatment

Enfermedad de Parkinson en el estado de Michoacán, evolución y tratamiento

Marcela García-Villa¹^*

Raúl Leal-Cantú²

Rosa G. Madrigal-Salas²

Ildefonso Rodríguez-Leyva³⁴

Mariana A. Quintana-Díaz⁵

Conne L. Gonzalez-García⁶

^¹Clinical Neurology Service, Hospital Star Médica, Morelia, Michoacán

^²Neurology Department, Hospital General “Dr. Miguel Silva,” Morelia, Michoacan

^³Neurology Department, Hospital Central “Dr. Ignacio Morones Prieto”, San Luis Potosí

^⁴Medicine School, Universidad Autónoma de San Luis Potosí, San Luis Potosí

^⁵Medicine and Health Scinence School, Tecnológico de Monterrey, Guadalajara, Jalisco

^⁶Clinical Research Unity, Hospital General “Dr. Miguel Silva,” Morelia, Michoacán. Mexico

Abstract

Objective:

This work is the first registry focused on knowing patients’ characteristics with Parkinson’s disease (PD), evolution and treatment used in the state of Michoacán.

Methods:

68 patients with PD from the neurology consultation of the General Hospital “Dr. Miguel Silva” from October 1, 2019, to December 31, 2019, who fulfilled the UKPDSBB criteria, were studied. Sociodemographic data, disease duration, and severity according to the Unified Parkinson’s Disease Rating Scale (MDS-UPDRS) and Hoehn and Yahr Scale were collected.

Results:

A total of 68 patients were included in the study. Seven of them were eliminated for not meeting the inclusion criteria. Of the 61 evaluated, 31 (50.8%) were women, the mean age was 68 years (± 9.8) and the age of diagnosis was 61 years (± 12.6). The predominant comorbidities were diabetes mellitus (16.4%), systemic arterial hypertension (44.3%), and depression (70.5%). The dominant phenotype was rigid-akinetic, with absence or slight tremor in 50.8%. About 36.1% had between 5 and 10 years of suffering from the disease. 36.1% had exposure to pesticides; 31.1% had a history of head trauma. There were 24.6% smoking and 31.1% alcoholism. The drugs most used for motor manifestations were levodopa/carbidopa in 83.6% and pramipexole in 31.1 %. In part I of the MDS-UPDRS scale, the mean score was 9.8 ± 6.0; part II 14.37 ± 9.6; part III 21.22 ± 12.4 and part IV 3.2 ± 3.69. HY, I occupied 37.7%; II 26.2%; III 23%; IV 9.8% and V 3.3%.

Conclusions:

In this population, the disease occurred without distinction of gender. The only treatment was pharmacological. Rehabilitation, the support of the psychiatrist and nutritionists, is essential for comprehensive management.

Keywords Parkinson’s disease; Mexico; Cross-sectional study

Resumen

Objetivo:

Este trabajo es el primer registro enfocado en conocer las características, evolución y tratamiento de los pacientes con enfermedad de Parkinson (EP) utilizados en el estado de Michoacán.

Material y métodos:

Se estudiaron 68 pacientes con EP de la consulta de neurología del Hospital General “Dr. Miguel Silva” del 1 de octubre de 2019 al 31 de diciembre de 2019, que cumplieran con los criterios de la UKPDSBB. Se recogieron datos sociodemográficos, duración y gravedad de la enfermedad según la Escala Unificada de Calificación de la Enfermedad de Parkinson (MDS-UPDRS) y la Escala de Hoehn y Yahr.

Resultados:

Se incluyó a un total de 68 pacientes. Siete de ellos fueron eliminados por no cumplir con los criterios de inclusión. De los 61 evaluados, 31 (50.8%) eran mujeres, la edad media fue de 68 años ± 9.8 años y la edad de diagnóstico fue de 61 años ± 12.6. Las comorbilidades predominantes fueron diabetes mellitus (16.4%), hipertensión arterial sistémica (44.3%) y depresión (70.5%). El fenotipo dominante fue rígido-acinético, con ausencia o leve temblor en el 50.8%. El 36.1% tenía entre 5 y 10 años de padecer la enfermedad. 36.1% tuvo exposición a plaguicidas y 31.1% tenía antecedentes de traumatismo craneoencefálico. Los fármacos más utilizados para las manifestaciones motoras fueron levodopa/carbidopa en el 83.6% y pramipexol en 31.1%. En la parte I de la escala MDS-UPDRS, la puntuación media fue de 9.8 ± 6,0; parte II, 14.37 ± 9.6; parte III 21.22 ± 12.4 y en la parte IV 3.2 ± 3.69. HY, I ocupó 37.5%; II 26.2%; III 23%; IV 9.8% y V 3.3%.

Conclusiones:

En esta población la enfermedad se presentó sin distinción de género. El único tratamiento fue farmacológico. La rehabilitación, el apoyo del psiquiatra y nutriología se hacen indispensables para el manejo integral.

Palabras clave Enfermedad de Parkinson; México; Estudio transversal

Introduction

Parkinson’s disease (PD) is a complex neurodegenerative adult-onset process and is the second most common proteinopathy after Alzheimer’s dementia¹.

The British surgeon James Parkinson is acknowledged for publishing the first description of the disease in his “Essay on the Shaking Palsy” in 1817². Three years later that the eponymous was suggested by the French neurologist Jean-Martin Charcot as “La Maladie de Parkinson.³,⁴”

In the present day, the prevalence and incidence of numerous neurological diseases have increased considerably in recent decades, especially those related to the aging process⁵. PD has been no stranger to this increase, as it is one of the most frequent disorders in neurology consultations⁶.

The etiology of PD is unknown, but it is attributed to a combination of environmental and genetic factors⁷. Dopaminergic denervation of the substantia nigra pars compacta projections to the striatal nucleus leads to an alteration in the basal ganglia’s normal physiology⁸. Age is the most consistent risk factor and, as the age of the general population increases, the prevalence of PD will steadily increase in the future⁹. In fact, neurodegenerative diseases are projected to overtake cancer as the second most common cause of death among the elderly by 2040 and the number of cases with PD to double between 2005 and 2030⁷,¹⁰.

The reported frequency of PD varies depending on the diagnostic criteria employed, the population studied, or the epidemiological methods used. The prevalence is estimated to be 0.3% of the general population and approximately 1% in those over 60. The estimated worldwide incidence ranges from 8 to 18/100,000 inhabitants/year¹¹. Almost all epidemiological studies have shown that both the incidence and prevalence of PD are higher in men than in women, suggesting a possible protective effect of estrogens¹²,¹³. Several environmental factors such as exposure to pesticides or repeated head trauma have been associated with an increased risk, while others such as caffeine, tobacco or alcohol consumption, or taking nonsteroidal anti-inflammatory drugs could be protective factors¹⁴,¹⁵.

Motor disturbances are the main clinical manifestations of PD. Due to the clinical heterogeneity of presentation, attempts have been made to classify the disease into subtypes, such as the tremor dominant and non-tremor dominant groups; the latter referred also as rigid-akinetic phenotype and includes the postural instability and gait disorder (PIGD) subtype¹⁶. This differentiation could have prognostic implications as the disease course differs between the subtypes and the tremor subtype having the best prognosis¹⁷.

Non-motor symptoms of PD have gained prominence in recent years because they can precede the classic motor symptoms and are a major determinant of patients’ quality of life¹⁸. The non-motor symptoms involve mood disorders, autonomic dysfunction, sleep disorders, sensory symptoms, and cognitive disturbances¹⁹,²⁰.

Ultimately, the role of preclinical detection of PD will be determined by the ability to emerge therapies to influence clinical outcomes²¹. Conventional treatment often does not provide adequate motor control; as the patient suffers a progressive lack of efficacy of dopaminergic therapy fluctuations and dyskinesias appear, becoming a complex therapeutic challenge²². More than 80% of subjects with PD after 15-20 years of evolution present: dementia, freezing of gait, and falls resulting in fractures in up to 35% of cases²²,²³.

Materials and methods

This is an observational, descriptive, and cross-sectional study. Patients who fulfilled the UKPDSBB criteria (UK Parkinson’s Disease [PD] Society Brain Bank) attended at the General Hospital “Dr. Miguel Silva” and at the private neurology consultation of Neurologists belonging to the Michoacán Association of Neuroscience AC, from October 1, 2019, to December 31, 2019 were included in the study. Exclusion criteria were as follows: patients with parkinsonism which did not meet the UKPDSBB criteria, patients using drugs that could cause parkinsonism, patients with vascular parkinsonism, and patients who did not agree to participate in the study. The data collection consisted of sociodemographic variables (gender, age, age at onset, subtype at onset, and antiparkinsonian drug use), disease duration and severity according to the Unified Parkinson’s Disease Rating Scale (MDS-UPDRS), and Hoehn and Yahr (HY) scale.

This research protocol was reviewed and approved by the Research Ethics Committee of the General Hospital “Dr. Miguel Silva” of Morelia, Michoacán. All participants provided informed consent for participation.

Statistical analysis

Descriptive statistics were obtained, using measures of central tendency: mean, mode, median, and range; for quantitative variables; and proportions and percentages for qualitative variables that allowed tables and graphs to be made. The data obtained were collected on a data sheet and processed in the SPSS 23 statistical package.

Results

During the analyzed period, comprising from October 1, 2019, to December 31, 2019, a total of 68 patients agreed to participate, seven of them were excluded (due to the absence of scales application, the final diagnosis of drug-induced parkinsonism, or erroneous PD diagnosis). Of 61 patients who met the inclusion criteria, 31 (50.8%) were women and the mean age was 68 years ± 9.8 years. In respect of education, the majority (42.6%) had only elementary school education, 4.9% had no formal education but knew how to read and write their name, 6.6% were unschooled, while only 1.6% had a postgraduate degree. Concerning other sociodemographic variables, 70.5% were married, 23.0% were widowed, and 6.6% were unmarried. The majority of this population is active, 34.4% are housewives, 29.5% are employed, and the same percentage is unemployed, with only one subject continuing his undergraduate studies.

The mean age of diagnosis of Parkinson’s disease was 61 years ± 12.6. The age of onset of motor symptoms was questioned; however, the patients did not know it, although 80% referred from 4 to 8 months before diagnosis. Three patients (4.9%) reported a family history of Parkinson’s disease. The main comorbidities presented were depression (70.5%), systemic arterial hypertension (44.3%), diabetes mellitus (16.4%), cancer (6.6%), chronic renal insufficiency (3.3%), and heart disease (3.3%). The patients were graded, and the Unified Parkinson’s Disease Scale MDS-UPDRS was used to identify the dominant clinical phenotype. They were divided into four phenotypes: (1) tremor-predominant phenotype, (2) rigid-kinetic phenotype with absence or mild tremor, (3) phenotype with instability and gait disorder known as PIGD, and (4) mixed or indeterminate clinical phenotype. The predominant phenotype was rigid-akinetic, with absence or slight tremor in 50.8%. Of the total sample, 36.1% had been suffering from the disease for 5 to 10 years. With concern of risk factors, 22 patients (36.1%) had exposure to pesticides and 19 (31.1%) had a history of craniocerebral trauma. As of protective factors, 15 patients (24.6%) were found to be smokers.

The most commonly used medication for motor manifestations was levodopa/carbidopa in 83.6%, pramipexole in 31.1%, and rasagiline in 14.8%. However, biperiden is not included in the primary treatment of PD, and it was found to be still used in 21.3%. As for treatment for dyskinesias/fluctuations, only 10% used amantadine. For the treatment of depression and anxiety, 11.5% used citalopram and 6.6% used clonazepam. For psychosis, clozapine used 6.6%, and quetiapine used 4.9%. For REM sleep behavior disorder, clonazepam was used in 18% and melatonin in 6.6%. No drugs to treat orthostatic hypotension were found. Domperidone and sennosides were used with 6.6% frequency each; 11.5% took omeprazole for gastritis associated with gastrointestinal problems. The 8.2% used tamsulosin for genitourinary dysfunction, although it should be noted that this drug was taken for prostate problems, not for voiding problems associated with PD (Table 1).

Table 1 Most used drugs for motor and non-motor manifestations in PD. Biperiden was used in 21.3% even though it’s outside the basic treatment for PD

Medication	Used for	Percentage
Levodopa/carbidopa	Motor manifestations	83.6
Pramipexole	Motor manifestations	31.1
Biperidene	Motor manifestations	21.3
Rasagiline	Motor manifestations	14.8
Amantadine	Dyskinesias/fluctuations	10
Citalopram	Depression and anxiety	11.5
Clonazepam	Depression and anxiety	6.6
Clozapine	Psychosis	6.6
Quetiapine	Psychosis	4.9
Clonazepam	Rem behavioral sleep disorder	18
Melatonin	Rem behavioral sleep disorder	6.6
Domperidone	Gastrointestinal dysfunction	6.6
Sennosides	Gastrointestinal dysfunction	6.6

PD: Parkinson’s disease.

From evaluating patients with the MDS-UPDRS, we obtained the following results: the mean scores of the non-motor experiences of daily living (part I) were 9.8 ± 6.0, of the motor experiences of daily living (part II) were 14.37 ± 9.6, of the motor examination (part III) were 21.22 ± 12.4, and of motor complications (part IV) were 3.2 ± 3.69. When considering the four aspects of the scale, the mean overall score was 48.5 ± 25.9. Figures 1, 2, 3, and 4 show the percentage of the subscales of the MDS-UPDRS parts I, II, III, and IV, respectively.

Figure 1 Proportions of non-motor experiences of daily living.

Figure 2 Proportions of motor experiences of daily living.

Figure 3 Proportion of motor symptoms.

Figure 4 Proportion of motor complications. The time in the off stage and dyskinesias ranked as minimum in 44.3% and 34.4%, respectively.

According to the Hoehn and Yahr scale, Stage I occupied 37.7%, Stage II 26.2%, Stage III 23%, Stage IV 9.8%, and Stage V 3.3% (Figure 5).

Figure 5 Hoehn and Yahr scale stages.

Discussion

To the best of our knowledge, this is the first study in the state of Michoacán, Mexico, that evaluates Parkinson’s disease’s characteristics. Of the 61 patients who participated in the study, 50.8% were female and 49.2% were male. The presentation age was 68 years ± 9.8 years, which is similar to that reported internationally; as for gender, the disease presented equally. However, the literature indicates a predominance in the male gender¹,²⁴. In comparison with the Mexican PD Registry (ReMePARK), a multicenter cohort study published in 2013 provided the first insight into the motor, non-motor, and genetic determinants of Parkinson’s disease, the mean age of the patients was 64.7 ± 12.9 years²⁴.

The treatment of symptoms should be adapted to the evolution, phase of the disease, type of symptomatology, and disability. Approximately 80% of patients respond adequately to levodopa initially. Still, motor symptom control will gradually diminish over the next 2-5 years. Around 50% of them will develop disabling side effects (motor fluctuations, peak-dose dyskinesias, and dopaminergic dysregulation syndrome)²⁵. The DATATOP study proposed that there is no loss of response to levodopa after long-term therapy. However, the deterioration of these patients represents the disease’s progression; in general, the effect on tremor, rigidity, and bradykinesia does not change, but other alterations such as speech, postural responses, and gait are increased²³,²⁵. Patients who have no response to dopaminergic treatment can be benefited from the various pharmacological strategies. Other therapies use subcutaneous perfusion of apomorphine, continuous intestinal perfusion of levodopa/carbidopa, and deep brain stimulation (DBS)²⁶. Although those therapies effectively improve motor complications and non-motor aspects of PD, they are different in goals, benefits profiles, and risks. The proper selection for each treatment is a determining for the possibilities of the treatment success²⁶. The magnetic resonance imaging-guided by high-intensity focused ultrasound (MRI/FUS) has led to an interest in lesional procedures for tremor²⁷. Functional neurosurgery procedure through MRI/FUS offers a safe and efficient noninvasive therapeutic lesion possibility²⁸. The term “advanced therapies” based on experimental cell or gene therapies may generate further confusion in a lay setting, as many PD patients will not be candidates for these therapies²⁹. TRANSEURO is a European multicenter open-label study using human fetal dopamine cells and will be completed in 2021³⁰.

Unfortunately, we do not have therapies such as subcutaneous perfusion of apomorphine, continuous intestinal perfusion of levodopa/carbidopa, or DBS, neither MRI/FUS. To address the question which provides more remarkable improvement: optimal medical therapy or DBS, 225 patients from 7 Veterans Affairs departments, and six university hospitals were studied in a randomized controlled study designed to compare the effects of DBS (STN, n = 60; or GPi, n = 61) and “best medical therapy” (n =134) after 6 months of treatment. Patients treated with DBS gained a mean score of 4.6 h/day without dyskinesia than 0 h/day for patients receiving best medical therapy (p < 0.001). Furthermore, motor function improved by five or more points on the UPDRS motor assessment in 71% of DBS and 32% in medical therapy patients³¹. It is expected that health services in our country will have available specific treatment alternatives for patients with PD in the future.

In contrast to what is reported in the literature, it is noteworthy that the predominant phenotype found in our study was rigid-akinetic, with no or mild tremor, probably due to this study’s limitations, follow-up time was short.

Chen et al. concluded that there is sufficient evidence to suggest that non-pharmacological therapies (e.g., behavioral-behavioral therapy) are highly effective in treating PD patients’ anxiety³². In our setting, there are no non-pharmacological therapies, and pharmacological treatments are insufficient to treat anxiety and depression, so the urgency of multidisciplinary and comprehensive work is evident so that the patient with PD can achieve a better quality of life. Similar to Dobkin et al.,³³ most patients with PD suffer from some degree of depression.

Non-motor symptoms may be divided in dysautonomic, neuropsychiatric, sleep, and sensory disorders. Rodriguez-Violante et al. in their study prevalence of non-motor dysfunction among Parkinson’s disease patients from a tertiary referral center in Mexico City evaluated the prevalence of these symptoms in a sample of Mexican patients with PD who attended a neurological referral center using the non-motor symptom questionnaire and the non-motor symptom scale, found that the prevalence of non-motor symptoms among Mexican patients with PD is similar to other countries. Mood, cognitive, and perceptual symptoms seem to be more severe in our population³⁴. In our study, we found depression in 70.5% of the patients.

The comorbidities found in patients with PD by Nataraj and Rajput³⁵, compared with those found in this study, are approximate. Comparing their results to ours: systemic arterial hypertension in 31.1% versus 44.3%; diabetes mellitus in 12.9% versus 16.4%; and non-smokers in 65.5% versus 75.4%. Smoking may be important as it links nicotine as a protector of dopaminergic neurons since it has been shown to stimulate dopamine release in the striatum and preserve dopaminergic function in experimental models³⁶.

Related to the H-Y staging, Weintraub et al. reported the stage distribution as follows: H-YI (12.7%); H-YII (54.5%); HY-III (27.6%); and HY-IV (5.2%)³⁷. In our study, the result was as follows: Stages I (37.7%), II (26.2%), III (23%), IV (9.8%), and V (3.3%).

The exposure to pesticides found in this study was 36.1%, which corresponds to more than one-third of the population studied. Pesticide exposure has been described to be associated with an increased risk of PD, with an odds ratio ranging from 1.6 to 7. Based on epidemiological studies supporting an association between pesticide exposure and PD, an animal model of PD pathogenesis has been proposed. Continuous infusion of rotenone into the jugular vein of rats for several weeks produced highly selective degeneration of the nigrostriatal dopaminergic pathway, associated clinically with bradykinesia and rigidity, and pathologically with staining of cytoplasmic fibrillar inclusions for ubiquitin and alpha-synuclein³⁸.

Despite the increase in PD, research in Latin American PD patients remains scarce³⁹. The growing population growth in Latin America highlights the importance of PD research in this population, and there are some indications that the prevalence of PD in Mexico will double in 20 years, highlighting the importance of PD research studies in more regions of our country⁴⁰.

Conclusions

Considering that PD is progressive and degenerative, it is necessary to develop preventive strategies to reduce the impact of complications on patients’ quality of life; this would be achieved with interdisciplinary work covering all the aspects needed for a better general condition. The patients’ medical insurance does not cover the high costs of pharmacological and non-pharmacological therapies, such as Sistema de Protección Social en Salud, Instituto Mexicano del Seguro Social, or the Instituto de Seguridad y Servicios Sociales de los Trabajadores del Estado, not having a dimension of this problem, hinders the care of this disease in the State of Michoacán.

On the other hand, the increasing growth of PD in Mexico highlights the importance of more PD research studies in our country.

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FundingThis research has not received any specific grant from public, commercial, or non-profit sector agencies.

Ethical disclosures

Protection of human and animal subjects. The authors declare that no experiments were performed on humans or animals for this study.

Confidentiality of data. The authors declare that they have followed the protocols of their work center on the publication of patient data.

Right to privacy and informed consent. The authors have obtained the written informed consent of the patients or subjects mentioned in the article. The corresponding author is in possession of this document.

Received: March 01, 2021; Accepted: August 31, 2021

^* Correspondence:Marcela García-Villa E-mail: margarvi@hotmail.com

^{Conflicts of interest}

The authors declare that they have no conflicts of interest.

Instituto Nacional de Cardiología Ignacio Chávez. Published by Permanyer. This is an open access article under the CC BY-NC-ND license