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Management of Parkinson's disease

January 29, 2023

Li, Xuening; Gao, Zixuan; Yu, Huasen; Gu, Yan; Yang, Guang (2022). "Effect of Long-term Exercise Therapy on Motor Symptoms in Parkinson Disease Patients: A Systematic Review and Meta-analysis of Randomized Controlled Trials". American Journal of Physical Medicine & Rehabilitation. 101 (10): 905–912. doi:10.1097/PHM.0000000000002052. PMID 35695530. S2CID 252225251 – via Ovid.

Management of Parkinson's disease
SpecialtyNeurology
[edit on Wikidata]

In the management of Parkinson's disease, due to the chronic nature of Parkinson's disease (PD), a broad-based program is needed that includes patient and family education, support-group services, general wellness maintenance, exercise, and nutrition. At present, no cure for the disease is known, but medications or surgery can provide relief from the symptoms.

While many medications treat Parkinson's, none actually reverses the effects of the disease. Furthermore, the gold-standard treatment varies with the disease state. People with Parkinson's, therefore, often must take a variety of medications to manage the disease's symptoms.[1] Several medications currently in development seek to better address motor fluctuations and nonmotor symptoms of PD. However, none is yet on the market with specific approval to treat Parkinson's.[2]

Medication

 
Pharmacological treatment of Parkinson's disease

The main families of drugs useful for treating motor symptoms are levodopa, dopamine agonists, and MAO-B inhibitors.[3] The most commonly used treatment approach varies depending on the disease stage. Two phases are usually distinguished: an initial phase in which the individual with PD has already developed some disability which requires pharmacological treatment, and a second stage in which the patient develops motor complications related to levodopa usage.[3] Treatment in the initial state aims to attain an optimal tradeoff between good management of symptoms and side effects resulting from enhancement of dopaminergic function. The start of L-DOPA treatment may be delayed by using other medications such as MAO-B inhibitors and dopamine agonists, in the hope of delaying the onset of dyskinesias.[3] In the second stage, the aim is to reduce symptoms while controlling fluctuations of the response to medication. Sudden withdrawals from medication, and overuse by some patients, also must be controlled.[3] When medications are not enough to control symptoms, surgical techniques such as deep brain stimulation can relieve the associated movement disorders.[4]

Levodopa

 
Stalevo, a commercial preparation combining entacapone, levodopa, and carbidopa for treatment of Parkinson's disease
 
Circuits of the basal ganglia in treatment of Parkinson's disease – model of the effect of medication on motor symptoms: levodopa, dopamine agonists and MAO-B inhibitors stimulate excitatory signals from the thalamus to the cerebral cortex by effects on the striatum, compensating for decreased dopaminergic signals from substantia nigra (seen at bottom right).

Levodopa (or L-DOPA) has been the most widely used treatment for over 30 years.[3] L-DOPA is transformed into dopamine in the dopaminergic neurons by dopa-decarboxylase.[3] Since motor symptoms are produced by a lack of dopamine in the substantia nigra, the administration of L-DOPA temporarily diminishes the motor symptoms.[3]

Only 5–10% of L-DOPA crosses the blood–brain barrier. The remainder is often metabolised to dopamine elsewhere, causing a wide variety of side effects including nausea, dyskinesias, and stiffness.[3] Carbidopa and benserazide are peripheral dopa decarboxylase inhibitors.[3] They inhibit the metabolism of L-DOPA in the periphery, thereby increasing levodopa delivery to the central nervous system. They are generally given as combination preparations with levodopa.[3] Existing preparations are carbidopa/levodopa (co-careldopa, trade names Sinemet, Pharmacopa, Atamet) and benserazide/levodopa (co-beneldopa, trade name Madopar). Levodopa has also been related to a dopamine dysregulation syndrome, which is a compulsive overuse of the medication, and punding.[5]

Controlled, slow-release versions of Sinemet and Madopar spread out the effect of the levodopa. Duodopa is a combination of levodopa and carbidopa. Slow-release levodopa preparations have not shown an increased control of motor symptoms or motor complications when compared to immediate-release preparations.[3]

Tolcapone inhibits the catechol-O-methyltransferase (COMT) enzyme, which degrades dopamine and levadopa, thereby prolonging the therapeutic effects of levodopa.[3] It, alongside inhibitors of peripheral dopa decarboxylase, have been used to complement levodopa. However, due to its possible side effects such as liver failure, it is limited in its availability.[3] A similar drug, entacapone, has not been shown to cause significant alterations of liver function and maintains adequate inhibition of COMT over time.[3] Entacapone is available for treatment alone (COMTan) or combined with carbidopa and levodopa (Stalevo).[3]

Levodopa results in a reduction in the endogenous formation of L-DOPA, and eventually becomes counterproductive. Levodopa preparations lead in the long term to the development of motor complications characterized by involuntary movements called dyskinesias and fluctuations in the response to medication.[3] When this occurs, PD patients change rapidly from stages with good response to medication and few symptoms ("on" state) to phases with no response to medication and important motor symptoms ("off" state).[3] For this reason, levodopa doses are kept as low as possible while maintaining functionality.[3] Delaying the initiation of dopatherapy, using instead alternatives for some time, is also common practice.[3] A former strategy to reduce motor complications was to withdraw patients from L-DOPA for some time. It is discouraged now since it can bring dangerous side effects such as neuroleptic malignant syndrome.[3] Most people eventually need levodopa and later develop motor complications.[3]

The on-off phenomenon is an almost invariable consequence of sustained levodopa treatment in patients with Parkinson's disease. Phases of immobility and incapacity associated with depression alternate with jubilant thaws. Both pharmacokinetic and pharmacodynamic factors are involved in its pathogenesis, but evidence is presented to indicate the importance of levodopa handling has been underestimated and progressive reduction in the storage capacity of surviving nigrostriatal dopamine terminals is not a critical factor. Redistribution of levodopa dosage which may mean smaller, more frequent doses, or larger less frequent increments, may be helpful in controlling oscillations in some patients. Dietary protein restriction and the use of selegiline and bromocriptine may also temporarily improve motor fluctuations. New approaches to management include the use of subcutaneous apomorphine, controlled-release preparations of levodopa with a peripheral dopa decarboxylase inhibitor and the continuous intraduodenal administration of levodopa.[medical citation needed]

In animal models it was shown that the intake of adenosine receptor antagonists together with levodopa can amplify its therapeutic effects.[6][7]

Dopamine agonists

Dopamine agonists in the brain have a similar effect to levodopa since they bind to dopaminergic postsynaptic receptors.[3] Dopamine agonists were initially used for patients experiencing on-off fluctuations and dyskinesias as a complementary therapy to levodopa, but they are now mainly used on their own as an initial therapy for motor symptoms with the aim of delaying motor complications.[3][8] When used in late PD, they are useful at reducing the off periods.[3] Dopamine agonists include bromocriptine, pergolide, pramipexole, ropinirole, piribedil, cabergoline, apomorphine, and lisuride.

Agonists produce significant, although mild, side effects including somnolence, hallucinations, insomnia, nausea, and constipation.[3] Sometimes, side effects appear even at the minimal clinically efficacious dose, leading the physician to search for a different agonist or kind of drug.[3] When compared with levodopa, while they delay motor complications, they control worse symptoms.[3] Nevertheless, they are usually effective enough to manage symptoms in the initial years.[9] They are also more expensive.[9] Dyskinesias with dopamine agonists are rare in younger patients, but along other side effects, more common in older patients.[9] All this has led to agonists being the preferential initial treatment for the former as opposed to levodopa in the latter.[9] Agonists at higher doses have also been related to a wide variety of impulse-control disorders.[5]

Apomorphine, which is a dopamine agonist not orally administered, may be used to reduce off periods and dyskinesia in late PD.[3] Since secondary effects such as confusion and hallucinations are not rare, patients under apomorphine treatment should be closely monitored.[3] Apomorphine can be administered by subcutaneous injection using a small pump which is carried by the patient. A low dose is automatically administered throughout the day, reducing the fluctuations of motor symptoms by providing a steady dose of dopaminergic stimulation. After an initial "apomorphine challenge" in hospital to test its effectiveness and brief patient and primary caregiver (often a spouse or partner), the latter of whom takes over maintenance of the pump. The injection site must be changed daily and rotated around the body to avoid the formation of nodules. Apomorphine is also available in a more acute dose as an autoinjector pen for emergency doses such as after a fall or first thing in the morning. Nausea and vomiting are common, and may require domperidone (an antiemetic).[medical citation needed]

In a study evaluating the efficacy of dopamine agonists compared to levodopa, the results showed patients who took dopamine agonists were less likely to develop dyskinesia, dystonia, and motor fluctuations, although were more likely to discontinue therapy due to negative side effects such as nausea, edema, constipation, etc.[medical citation needed]

MAO-B inhibitors

Monoamine oxidase inhibitors (selegiline and rasagiline) increase the level of dopamine in the basal ganglia by blocking its metabolization. They inhibit monoamine oxidase-B (MAO-B) which breaks down dopamine secreted by the dopaminergic neurons. Therefore, reducing MAO-B results in higher quantities of L-DOPA in the striatum.[3] Similarly to dopamine agonists, MAO-B inhibitors improve motor symptoms and delay the need of taking levodopa when used as monotherapy in the first stages of the disease, but produce more adverse effects and are less effective than levodopa. Evidence on their efficacy in the advanced stage is reduced, although it points towards them being useful to reduce fluctuations between on and off periods.[3] Although an initial study indicated selegiline in combination with levodopa increased the risk of death, this has been later disproven.[3]

Metabolites of selegiline include L-amphetamine and L-methamphetamine (not to be confused with the more potent dextrorotary isomers). This might result in side effects such as insomnia. Another side effect of the combination can be stomatitis. Unlike other nonselective monoamine oxidase inhibitors, tyramine-containing foods do not cause a hypertensive crisis.[medical citation needed]

Other drugs

Some evidence indicates other drugs such as amantadine and anticholinergics may be useful as treatment of motor symptoms in early and late PD, but since the quality of evidence on efficacy is reduced, they are not first-choice treatments.[3] In addition to motor symptoms, PD is accompanied by a range of different symptoms. Different compounds are used to improve some of these problems.[10][11] Examples are the use of clozapine for psychosis, cholinesterase inhibitors for dementia, modafinil for day somnolence, and atomoxetine for executive dysfunction.[10][11][12]

A preliminary study indicates taking donepezil (Aricept) may help prevent falls in people with Parkinson's. Donepezil boosts the levels of the neurotransmitter acetylcholine, and is currently an approved therapy for the cognitive symptoms of Alzheimer's disease.[13] In the study, participants taking donepezil experienced falls half as often as those taking a placebo, and those who previously fell the most showed the most improvement.[14]

The introduction of clozapine (Clozaril) represents a breakthrough in the treatment of psychotic symptoms of PD. Prior to its introduction, treatment of psychotic symptoms relied on reduction of dopamine therapy or treatment with first generation antipsychotics, all of which worsened motor function. Other atypical antipsychotics useful in treatment include quetiapine (Seroquel), ziprasidone (Geodon), aripiprazole (Abilify), and paliperidone (Invega). Clozapine is believed to have the highest efficacy and lowest risk of extrapyramidal side effect.[12]

Getting medication on time

Parkinson's patients who do not get the correct medicine at the right time when they are in hospital, (frequently they are in hospital due to unrelated illnesses) sometimes cannot talk or walk. The health of a majority deteriorated due to unsatisfactory medication management when they are in hospital. Parkinson's UK believes the NHS could save up to £10m a year and improve the care of Parkinson's patients if mandatory training is introduced for all hospital staff.[15]

Parkinson UK found:

  • "Nearly two thirds of people who have Parkinson's don't always get their medication on time in hospital."
  • "More than three quarters of people with Parkinson's that we asked reported that their health deteriorated as a result of poor medication management in hospital."
  • "Only 21% of respondents told us they got their medication on time without having to remind hospital staff."[16]

Surgery

 
Illustration showing an electrode placed deep-seated in the brain

Treating PD with surgery was once a common practice, but after the discovery of levodopa, surgery was restricted to only a few cases.[17] Studies in the past few decades have led to great improvements in surgical techniques, and surgery is again being used in people with advanced PD for whom drug therapy is no longer sufficient.[17]

Less than 10% of those with PD qualify as suitable candidates for a surgical response. The three different mechanisms of surgical response for PD are: ablative surgery, (the irreversible burning or freezing of brain tissue), stimulation surgery or deep brain stimulation (DBS), and transplantation or restorative surgery.[18]

Target areas for DBS or lesions include the thalamus, the globus pallidus (the lesion technique being called pallidotomy), or the subthalamic nucleus.[17]

Neuroablative lesion surgery

Neuroablative lesion surgery locates and destroys, by heat, the parts of the brain associated with producing Parkinsonian neurological symptoms. The procedures generally involve a thalamotomy and/or pallidotomy. A thalamotomy is the destruction of a part of the thalamus, in particular the ventralis intermedius, to suppress tremor in 80-90% of patients. If rigidity and akinesia are apparent, the subthalamis nucleus is then the site of ablation.

A pallidotomy involves the destruction of the globus pallidus, in particular the globus pallidus interna, in patients with Parkinson's who have rigidity and akinesia.

Because it is difficult to accurately measure the amount of tissue to be destroyed, tremors not uncommonly persist through multiple courses of surgery, since tissue is irreversibly damaged and removed and testing smaller areas of tissue is safer to prevent serious complications, such as a stroke or paralysis.[citation needed]. This method has been generally replaced by deep brain surgery.

Deep brain stimulation

Deep brain stimulation (DBS) is presently the most used method of surgical treatment because it does not destroy brain tissue, it is reversible, and it can be tailored to individuals at their particular stage of disease. DBS employs three hardware components: a neurostimulator, also called an implanted pulse generator (IPG), which generates electrical impulses used to modulate neural activity, a lead wire which directs the impulses to a number of metallic electrodes towards the tip of the lead near the stimulation target, and an extension wire that connects the lead to the IPG. The IPG, which is battery-powered and encased in titanium, is traditionally implanted under the collarbone, and is connected by the subcutaneous extension to the lead, which extends from outside the skull under the scalp down into the brain to the target of stimulation. The IPG, or the entire three-component system, are sometimes referred to as a brain pacemaker, due to the precedence and renown of cardiac pacemakers and similarities in the components of both types of systems.[medical citation needed]

The preoperative targeting of proper implantation sites can be accomplished by the indirect and direct methods. The indirect method uses computer tomography, magnetic resonance imaging, or ventriculography to locate the anterior and posterior commissures and then employs predetermined coordinates and distances from the intercommissural line to define the target area. Subsequent histologically defined atlas maps can also be used to verify the target area. The direct method provides visualization and targeting of deep nuclei by applying stereotactic preoperative MRI, which unlike the indirect method, takes into account the anatomic variation of the nuclei's size, position, and functional segregation amongst individuals.[19]

Electrophysial functional mapping, a tool used in both methods to verify the target nuclei, has come under scrutiny due to its associated risks of hemorrhages, dysarthria or tetanic contractions. Recently, susceptibility-weighted imaging, a type of MRI, has shown incredible power in its ability to distinguish these deep brain nuclei and is being used in DBS to reduce the overuse of EFM.[20]

DBS is recommended to PD patients without important neuropsychiatric contraindications who have motor fluctuations and tremor badly controlled by medication, or to those who are intolerant to medication.[4]

DBS is effective in suppressing symptoms of PD, especially tremor. A recent clinical study led to recommendations on identifying which Parkinson's patients are most likely to benefit from DBS.[4]

Diet

See also: Dietary management of Parkinson's disease

Muscles and nerves that control the digestive process may be affected by PD, so it is common to experience constipation and gastroparesis (food remaining in the stomach for a longer period of time than normal).[21] A balanced diet is recommended to help improve digestion. Diet should include high-fiber foods and plenty of water.[21] Levodopa and proteins use the same transportation system in the intestine and the blood–brain barrier, competing between them for access.[21] When taken together, the consequences of such competition is a reduced effectiveness of the drug.[21] Therefore, when levodopa is introduced, excessive proteins are discouraged, while in advanced stages, additional intake of low-protein products such as bread or pasta is recommended for similar reasons.[21] To minimize interaction with proteins, levodopa is recommended to be taken 30 minutes before meals.[21] At the same time, regimens for PD restrict proteins during breakfast and lunch and are usually taken at dinner.[21] As the disease advances, dysphagia may appear. In such cases, specific measures include the use of thickening agents for liquid intake, special postures when eating, and gastrostomy in the worst cases.[21]

Rehabilitation

Studies of rehabilitation in Parkinson's disease are scarce and are of low quality.[22][23] Partial evidence indicates speech or mobility problems can improve with rehabilitation.[22][23] Regular physical exercise and/or therapy can be beneficial to maintain and improve mobility, flexibility, strength, gait speed, and quality of life.[23] Exercise may also improve constipation. Exercise interventions have been shown to benefit patients with Parkinson's disease in regards to physical functioning, health-related quality of life, and balance and fall risk. In a review of 14 studies examining the effects of exercise on persons with Parkinson's disease, no adverse events or side effects occurred following any of the exercise interventions.[24] Five proposed mechanisms by which exercise enhances neuroplasticity are known. Intensive activity maximizes synaptic plasticity; complex activities promote greater structural adaptation; activities that are rewarding increase dopamine levels and therefore promote learning/relearning; dopaminergic neurones are highly responsive to exercise and inactivity ("use it or lose it"); and where exercise is introduced at an early stage of the disease, progression can be slowed.[21][25] One of the most widely practiced treatments for speech disorders associated with Parkinson's disease is the Lee Silverman voice treatment (LSVT), which focuses on increasing vocal loudness and has an intensive approach of one month.[22][26] Speech therapy and specifically LSVT may improve voice and speech function.[22] Occupational therapy (OT) aims to promote health and quality of life by helping people with the disease to participate in as many activities of their daily living as possible.[22] Few studies have been conducted on the effectiveness of OT and their quality is poor, although some indication shows it may improve motor skills and quality of life for the duration of the therapy.[22][27]

For monitoring patients with Parkinson's disease, research teams are examining whether virtual house calls can replace visits to clinical facilities. In a trial of such video visits, patients preferred the remote specialist after 1 year.[28] The home care was considered convenient but requires access to and familiarity with Internet-enabled technologies.

Exercise

Regular physical exercise with or without physiotherapy can be beneficial to maintain and improve mobility, flexibility, strength, gait speed, and quality of life.[23][29] Parkinson's Disease often causes sedentary behaviours resulting in lower quality of life in the long-term. [30]In terms of improving flexibility and range of motion for patients experiencing rigidity, generalized relaxation techniques such as gentle rocking have been found to decrease excessive muscle tension. Other effective techniques to promote relaxation include slow rotational movements of the extremities and trunk, rhythmic initiation, diaphragmatic breathing, and meditation techniques.[31] Common changes in gait associated with the disease such as hypokinesia (slowness of movement), shuffling and decreased arm swing are addressed by a variety of strategies to improve functional mobility and safety. Goals with respect to gait during rehabilitation programs include improving gait speed, base of support, stride length, trunk and arm swing movement. Strategies include utilizing assistive equipment (pole walking and treadmill walking), verbal cueing (manual, visual and auditory), exercises (marching and PNF patterns) and varying environments (surfaces, inputs, open vs. closed).[32]

Strengthening exercises have led to improvements in strength and motor functions in patients with primary muscular weakness and weakness related to inactivity in cases of mild to moderate Parkinson's disease.[29] Patients perform exercises when at their best, 45 minutes to one hour after medication.[33] An 8-week resistance training study geared towards the lower legs found that patients with Parkinson's Disease gained abdominal strength, and improved in their stride length, walking velocity and postural angles.[34] Also, due to the forward flexed posture and respiratory dysfunctions in advanced Parkinson's disease, deep diaphragmatic breathing exercises are beneficial for improving chest wall mobility and vital capacity.[35] Exercise may correct constipation.[36]

Exercise training on a vibratory platform, also called whole body vibration (WBV) training, has been recently introduced as a training tool complementing standard physical rehabilitation programs for people with Parkinson's disease. Compared to no intervention, single sessions of WBV have resulted in improved motor ability, as reflected by Unified Parkinson's Disease Rating Scale (UPDRS) tremor and rigidity scores.[37][38] However, longer-term (3–5 weeks) WBV programs have not led to improved UPDRS motor scores compared to conventional exercises.[39][40] Furthermore, multiple sessions of WBV have failed to enhance mobility measures (i.e., the Timed Up and Go Test and 10-Meter Walking Test) in people with Parkinson's disease.[39][40] A recent review deemed that the evidence of the effects of WBV training on sensorimotor and functional performance remains inconclusive.[41]

Psychological treatments

Psychological treatment is based on cognitive-behavioral interventions. Cognitive behavioral therapy is confirmed as efficient for treatment of parkinsonian pain, insomnia, anxiety, depression, and impulse control disorders.[42] Treating Parkinson's disease engages a multidisciplinary approach, and includes a psychologist, because motor symptoms can be worsened by psychosocial factors like anxiety, phobia, and panic attacks.[42] Psychological treatment is tailored to each individual, based on clinical recommendations, especially if they have severe motor disability or cognitive problems.

Gait training

Patients with Parkinson's disease have an altered gait. There is a reduced gait speed and step length, increased axial rigidity, and impaired rhythmicity. These gait problems worsen as the disease continues. This is a major disease burden that markedly affects independence and quality of life.[43] Since it is proven that tremor-dominant and akinetic rigid types of Parkinson's disease have various different visuomotor deficiencies, like problems in visual perception and motor coordination, that can influence their gait training, it is recommended for them to receive neuropsychological assessment before physical therapy.[44]

Task-specific gait training may also lead to long-term gait improvement for patients with Parkinson's disease. Previous research studies have utilized body weight support systems during gait training, where individuals are suspended from an overhead harness with straps around the pelvic girdle as they walk on a treadmill. This form of gait training has been shown to improve long-term walking speed and a shuffling gait following a one-month intervention period.[45]

Studies are also looking at the effect of tai chi on gait performance, and balance in people with Parkinson's Disease.[46][47] The first study concluded that tai chi was ineffective since there was no improvement on gait performance and no improvement on the Part III score of the Unified Parkinson's Disease Rating Scale (UPDRS).[46] The second study found that patients taking tai chi improved on their UPDRS score, Timed Up and Go test, six-minute walk and backwards walking.[47] It did not however, show any improvements on their forward walking or their one leg stance test.[47]

Speech and occupational therapy

One of the most widely practiced treatments for speech disorders associated with Parkinson's disease is the Lee Silverman voice treatment (LSVT).[22][26] Speech therapy and specifically LSVT may improve speech.[22]

People with Parkinson's disease can develop dysarthria which is characterized by reduced speech intelligibility. Prosodically based treatments may help.[48]

Occupational therapy aims to promote health and quality of life by helping people with the disease to participate in as much of their daily routine as possible.[22] There is indication that occupational therapy may improve motor skills and quality of life for the duration of the therapy.[22][27]

Rhythmic auditory stimulation

Rhythmic auditory stimulation (RAS) is a neurological rehabilitation technique consisting in compensating the loss of motor regulation through an external sensory stimulation, mediated by the sound. This technique relies on the strong interaction between auditory and motor neural system. By synchronizing his footsteps on the emitted sound (that can be "metronome-like" cues or complex music) the patient can improves his gait speed and his stride length.[49]

Telemedicine

A 2017 one-year randomized controlled trial found that providing remote neurologic care to individuals with Parkinson's Disease in their own homes was feasible and as effective as in-person care. While it can be more difficult for remote caregivers to establish trust while providing remote care, that assessment of video visits in a patient's home found that, after four virtual visits over one year, individuals with Parkinson's Disease preferred their connection with the remote specialist to their local clinician.[50]

Benefits of telemedicine include convenience and cost-effectiveness, as the virtual in-home visits have been found to reduce travel costs and time for patients relative to in-office visits. Some studies have found that the technology supports personalized connections similar to the house calls of the past. Five randomized controlled trials indicated that quality of life was similar or improved for those receiving telemedicine care.[50][51]

Challenges related to telemedicine in treatment of individuals with Parkinson's Disease are related to the technological requirements, as patients and their friends or families must have access to and familiarity with Internet-based technologies.[52] In part because of these technological requirements, studies in the United States have tended to include few participants from ethnic minorities and disproportionately include more highly educated populations. One solution proposed to reduce social and economic barriers to access to remote care is to establish satellite teleneurology clinics in underserved regions.[51][50] Physicians cite barriers with inability to perform a full neurologic exam in addition to technology and reimbursement issues.[53]

New telemedicine technologies being used or evaluated in the context of telemedicine include proprietary wearables, self-sensing and adjusting closed loop systems, robotic technologies, smart devices to detect movements, programs to improve medication adherence, smart home integration, and artificial intelligence or machine learning-based systems.[54]

Palliative care

Palliative care is often required in the final stages of the disease, often when dopaminergic treatments have become ineffective. The aim of palliative care is to achieve the maximum quality of life for the person with the disease and those surrounding him or her. Some central issues of palliative are caring for patients at home while adequate care can be given there, reducing or withdrawing dopaminergic drug intake to reduce drug side effects and complications, preventing pressure ulcers by management of pressure areas of inactive patients, and facilitating the patient's end-of-life decisions for the patient, as well as involved friends and relatives.[55]

Other treatments

Repetitive transcranial magnetic stimulation temporarily improves levodopa-induced dyskinesias.[56] Its full usefulness in PD is an open research field.[57] Different nutrients have been proposed as possible treatments; however, no evidence shows vitamins or food additives improve symptoms.[58] Not enough evidence exists to suggest that acupuncture, and practice of qigong or t'ai chi have any effect on symptoms.[59][60][61] Fava and velvet beans are natural sources of L-DOPA and are taken by many people with PD. While they have shown some effectiveness,[62] their intake is not free of risks. Life-threatening adverse reactions have been described, such as the neuroleptic malignant syndrome.[63][64] Faecal transplants may have a beneficial impact on symptoms.[65]

History

 
An 1893 photograph of Jean-Martin Charcot, who made important contributions to the understanding of the disease, including the proposal of anticholinergics as treatments for tremor

The positive albeit modest effects of anticholinergic alkaloids obtained from the plant of the belladonna were described during the 19th century by Charcot, Erb, and others. Modern surgery for tremor, consisting of the lesioning of some of the basal ganglia structures was first tried in 1939, and was improved over the following 20 years.[66] Before this date, surgery consisted in lesioning the corticospinal pathway with paralysis instead of tremor as result. Anticholinergics and surgery were the only treatments until the arrival of levodopa, which reduced their use dramatically.[66][67]

Levodopa was first synthesized in 1911 by Casimir Funk, but it received little attention until the mid-20th century.[68] It entered clinical practice in 1967, and the first large study reporting improvements in people with Parkinson's disease resulting from treatment with levodopa was published in 1968. Levodopa brought about a revolution in the management of PD.[68][69] By the late 1980s deep brain stimulation emerged as a possible treatment, and it was approved for clinical use by the FDA in 1997.[70]

Research directions

See also: Parkinson's disease clinical research

No new PD treatments are expected in the short term, but several lines of research are active for new treatments.[71] Such research directions include the search of new animal models of the disease, and the potential usefulness of gene therapy, stem cells transplants, and neuroprotective agents.[72]

Animal models

The tragedy of a group of drug addicts in California in the early 1980s who consumed a contaminated and illicitly produced batch of the synthetic opiate MPPP brought to light MPTP as a cause of parkinsonian symptoms.[73] Other predominant toxin-based models employ the insecticide rotenone, the herbicide paraquat, and the fungicide maneb.[74] Models based on toxins are most commonly used in primates. Transgenic rodent models also exist.[75]

Gene therapy

Main article: Gene therapy in Parkinson's disease

Present treatments of Parkinson's disease provide satisfactory disease control for most early-stage patients.[76] However, present gold-standard treatment of PD using levodopa is associated with motor complications, and does not prevent disease progression.[76] More effective and long-term treatment of PD are urgently needed to control its progression.[76] In vivo gene therapy is a new approach for treatment of PD.[77] The use of somatic-cell gene transfer to alter gene expression in brain neurochemical systems is a novel alternative conventional treatment.[77]

Gene therapy is currently under investigation.[72][78] It involves the use of a noninfectious virus to shuttle a gene into a part of the brain. The gene used leads to the production of an enzyme which helps to manage PD symptoms or protects the brain from further damage.[72]

One of the gene therapy based approach involves gene delivery of neurturin and glial cell line-derived neurotrophic factor (GDNF) to the putamen in patients with advanced Parkinson's disease.[76] GDNF protects dopamine neurons in vitro and animal models of parkinsonism; neurturin is a structural and functional analogue of GDNF that protected dopamine neuron in animal model of the disease.[76] Despite open-label trials showing benefits of continuous infusion of GDNF, the results were not confirmed in double-blind studies.[76] This may be due to the distribution factor; the trophic factor was not distributed sufficiently throughout the target place.[76]

Another gene therapy of PD involved insertion of the glutamic acid decarboxylase (GAD) into the subthalamic nucleus.[77] GAD enzyme controls GABA productions.[77] In Parkinson's disease, the activity of both GABA efferents to the subthalamic nucleus and its target within the basal ganglia circuitry are affected.[77] This strategy used adeno-associated viral vector (AAV2) to deliver GAD to the subthalamic nucleus.[77] The trial was done to compare the effect of bilateral delivery of AAV2-GAD into the subthalamic nucleus with bilateral sham surgery in patients with advanced Parkinson's disease.[77] The study showed the first success of randomised, double-blind gene therapy trial for a neurodegenerative disease and justified the continued development of AAV2-GAD for treatment of PD.[77]

Neuroprotective treatments

 
While several chemical compounds such as GNDF (chemical structure pictured) have been proposed as neuroprotectors in PD, none has proven its efficacy.

Investigations on neuroprotection are at the forefront of PD research. Currently, no proven neuroprotective agents or treatments are available for PD. While still theoretical, neuroprotective therapy is based on the idea that certain neurons that produce dopamine and are susceptible to premature degeneration and cell death can be protected by the introduction of neuroprotective pharmaceuticals. This protection can occur before any symptoms manifest based on genetic risk, and also during early- or late-stage PD when other treatments have ceased their impact due to the progression of the disease. Accordingly, neuroprotective therapy seeks to delay the introduction of levodopa.

Several molecules have been proposed as potential treatments.[72] However, none of them has been conclusively demonstrated to reduce degeneration.[72] Agents currently under investigation include antiapoptotics (omigapil, CEP-1347), antiglutamatergics, monoamine oxidase inhibitors (selegiline, rasagiline), promitochondrials (coenzyme Q10, creatine), calcium channel blockers (isradipine) and growth factors (GDNF).[72] Preclinical research also targets alpha-synuclein.[71]

Selegiline

Selegiline is in a group of medications called monoamine oxidase type B (MAO-B) inhibitors.[79] Selegiline is used to help control the symptoms of Parkinson's disease in people who are taking levodopa and carbidopa combination (Sinemet). Selegiline may help people with PD by stopping the effects of levodopa/carbidopa from wearing off, and increasing the length of time levodopa/carbidopa continues to control symptoms.

Rasagiline

In response to potentially toxic amphetamine metabolites caused by selegiline, another promising treatment is in MAO B propargyl amine inhibitor rasagiline (N-propargyl-1-R-aminoindan, Azilect((R))). The oral bioavailability of rasagiline is 35%, it reaches T(max) after 0.5–1.0 hours and its half-life is 1.5–3.5 hours. Rasagiline undergoes extensive hepatic metabolism primarily by cytochrome P450 type 1A2 (CYP1A2). Rasagiline is initiated at 1-mg once-daily dose as monotherapy in early PD patients and at 0.5–1.0 mg once-daily as adjunctive to levodopa in advanced PD patients.[80]

Neural transplantation

Since early in the 1980s fetal, porcine, carotid or retinal tissues have been used in cell transplants for PD patients.[72] Although there was initial evidence of mesencephalic dopamine-producing cell transplants being beneficial, the best constructed studies up to date indicate that cell transplants have no effect.[72] An additional significant problem was the excess release of dopamine by the transplanted tissue, leading to dystonias.[81] Stem cell transplants are a main research recent target: they are easy to manipulate and when transplanted into the brains of rodents and monkeys, cells survive and improve behavioral abnormalities of the animals.[72][82] Nevertheless, use of fetal stem cells is controversial.[72] Some have proposed that such controversy may be overcome with the use of induced pluripotent stem cells from adults.[72]

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External links

  • at the Parkinson's Disease Foundation
  • PDtrials
  • Find What Treatments Are Possible

January 29, 2023
management, parkinson, disease, xuening, zixuan, huasen, yang, guang, 2022, effect, long, term, exercise, therapy, motor, symptoms, parkinson, disease, patients, systematic, review, meta, analysis, randomized, controlled, trials, american, journal, physical, m. Li Xuening Gao Zixuan Yu Huasen Gu Yan Yang Guang 2022 Effect of Long term Exercise Therapy on Motor Symptoms in Parkinson Disease Patients A Systematic Review and Meta analysis of Randomized Controlled Trials American Journal of Physical Medicine amp Rehabilitation 101 10 905 912 doi 10 1097 PHM 0000000000002052 PMID 35695530 S2CID 252225251 via Ovid This article has multiple issues Please help improve it or discuss these issues on the talk page Learn how and when to remove these template messages This article needs more medical references for verification or relies too heavily on primary sources Please review the contents of the article and add the appropriate references if you can Unsourced or poorly sourced material may be challenged and removed Find sources Management of Parkinson s disease news newspapers books scholar JSTOR November 2021 This article needs to be updated Please help update this article to reflect recent events or newly available information November 2021 Learn how and when to remove this template message Management of Parkinson s diseaseSpecialtyNeurology edit on Wikidata In the management of Parkinson s disease due to the chronic nature of Parkinson s disease PD a broad based program is needed that includes patient and family education support group services general wellness maintenance exercise and nutrition At present no cure for the disease is known but medications or surgery can provide relief from the symptoms While many medications treat Parkinson s none actually reverses the effects of the disease Furthermore the gold standard treatment varies with the disease state People with Parkinson s therefore often must take a variety of medications to manage the disease s symptoms 1 Several medications currently in development seek to better address motor fluctuations and nonmotor symptoms of PD However none is yet on the market with specific approval to treat Parkinson s 2 Contents 1 Medication 1 1 Levodopa 1 2 Dopamine agonists 1 3 MAO B inhibitors 1 4 Other drugs 1 5 Getting medication on time 2 Surgery 2 1 Neuroablative lesion surgery 2 2 Deep brain stimulation 3 Diet 4 Rehabilitation 4 1 Exercise 4 2 Psychological treatments 4 3 Gait training 4 4 Speech and occupational therapy 4 5 Rhythmic auditory stimulation 4 6 Telemedicine 5 Palliative care 6 Other treatments 7 History 8 Research directions 8 1 Animal models 8 2 Gene therapy 8 3 Neuroprotective treatments 8 3 1 Selegiline 8 3 2 Rasagiline 8 4 Neural transplantation 9 References 10 External linksMedication Edit Pharmacological treatment of Parkinson s disease The main families of drugs useful for treating motor symptoms are levodopa dopamine agonists and MAO B inhibitors 3 The most commonly used treatment approach varies depending on the disease stage Two phases are usually distinguished an initial phase in which the individual with PD has already developed some disability which requires pharmacological treatment and a second stage in which the patient develops motor complications related to levodopa usage 3 Treatment in the initial state aims to attain an optimal tradeoff between good management of symptoms and side effects resulting from enhancement of dopaminergic function The start of L DOPA treatment may be delayed by using other medications such as MAO B inhibitors and dopamine agonists in the hope of delaying the onset of dyskinesias 3 In the second stage the aim is to reduce symptoms while controlling fluctuations of the response to medication Sudden withdrawals from medication and overuse by some patients also must be controlled 3 When medications are not enough to control symptoms surgical techniques such as deep brain stimulation can relieve the associated movement disorders 4 Levodopa Edit Stalevo a commercial preparation combining entacapone levodopa and carbidopa for treatment of Parkinson s disease Circuits of the basal ganglia in treatment of Parkinson s disease model of the effect of medication on motor symptoms levodopa dopamine agonists and MAO B inhibitors stimulate excitatory signals from the thalamus to the cerebral cortex by effects on the striatum compensating for decreased dopaminergic signals from substantia nigra seen at bottom right Levodopa or L DOPA has been the most widely used treatment for over 30 years 3 L DOPA is transformed into dopamine in the dopaminergic neurons by dopa decarboxylase 3 Since motor symptoms are produced by a lack of dopamine in the substantia nigra the administration of L DOPA temporarily diminishes the motor symptoms 3 Only 5 10 of L DOPA crosses the blood brain barrier The remainder is often metabolised to dopamine elsewhere causing a wide variety of side effects including nausea dyskinesias and stiffness 3 Carbidopa and benserazide are peripheral dopa decarboxylase inhibitors 3 They inhibit the metabolism of L DOPA in the periphery thereby increasing levodopa delivery to the central nervous system They are generally given as combination preparations with levodopa 3 Existing preparations are carbidopa levodopa co careldopa trade names Sinemet Pharmacopa Atamet and benserazide levodopa co beneldopa trade name Madopar Levodopa has also been related to a dopamine dysregulation syndrome which is a compulsive overuse of the medication and punding 5 Controlled slow release versions of Sinemet and Madopar spread out the effect of the levodopa Duodopa is a combination of levodopa and carbidopa Slow release levodopa preparations have not shown an increased control of motor symptoms or motor complications when compared to immediate release preparations 3 Tolcapone inhibits the catechol O methyltransferase COMT enzyme which degrades dopamine and levadopa thereby prolonging the therapeutic effects of levodopa 3 It alongside inhibitors of peripheral dopa decarboxylase have been used to complement levodopa However due to its possible side effects such as liver failure it is limited in its availability 3 A similar drug entacapone has not been shown to cause significant alterations of liver function and maintains adequate inhibition of COMT over time 3 Entacapone is available for treatment alone COMTan or combined with carbidopa and levodopa Stalevo 3 Levodopa results in a reduction in the endogenous formation of L DOPA and eventually becomes counterproductive Levodopa preparations lead in the long term to the development of motor complications characterized by involuntary movements called dyskinesias and fluctuations in the response to medication 3 When this occurs PD patients change rapidly from stages with good response to medication and few symptoms on state to phases with no response to medication and important motor symptoms off state 3 For this reason levodopa doses are kept as low as possible while maintaining functionality 3 Delaying the initiation of dopatherapy using instead alternatives for some time is also common practice 3 A former strategy to reduce motor complications was to withdraw patients from L DOPA for some time It is discouraged now since it can bring dangerous side effects such as neuroleptic malignant syndrome 3 Most people eventually need levodopa and later develop motor complications 3 The on off phenomenon is an almost invariable consequence of sustained levodopa treatment in patients with Parkinson s disease Phases of immobility and incapacity associated with depression alternate with jubilant thaws Both pharmacokinetic and pharmacodynamic factors are involved in its pathogenesis but evidence is presented to indicate the importance of levodopa handling has been underestimated and progressive reduction in the storage capacity of surviving nigrostriatal dopamine terminals is not a critical factor Redistribution of levodopa dosage which may mean smaller more frequent doses or larger less frequent increments may be helpful in controlling oscillations in some patients Dietary protein restriction and the use of selegiline and bromocriptine may also temporarily improve motor fluctuations New approaches to management include the use of subcutaneous apomorphine controlled release preparations of levodopa with a peripheral dopa decarboxylase inhibitor and the continuous intraduodenal administration of levodopa medical citation needed In animal models it was shown that the intake of adenosine receptor antagonists together with levodopa can amplify its therapeutic effects 6 7 Dopamine agonists Edit Dopamine agonists in the brain have a similar effect to levodopa since they bind to dopaminergic postsynaptic receptors 3 Dopamine agonists were initially used for patients experiencing on off fluctuations and dyskinesias as a complementary therapy to levodopa but they are now mainly used on their own as an initial therapy for motor symptoms with the aim of delaying motor complications 3 8 When used in late PD they are useful at reducing the off periods 3 Dopamine agonists include bromocriptine pergolide pramipexole ropinirole piribedil cabergoline apomorphine and lisuride Agonists produce significant although mild side effects including somnolence hallucinations insomnia nausea and constipation 3 Sometimes side effects appear even at the minimal clinically efficacious dose leading the physician to search for a different agonist or kind of drug 3 When compared with levodopa while they delay motor complications they control worse symptoms 3 Nevertheless they are usually effective enough to manage symptoms in the initial years 9 They are also more expensive 9 Dyskinesias with dopamine agonists are rare in younger patients but along other side effects more common in older patients 9 All this has led to agonists being the preferential initial treatment for the former as opposed to levodopa in the latter 9 Agonists at higher doses have also been related to a wide variety of impulse control disorders 5 Apomorphine which is a dopamine agonist not orally administered may be used to reduce off periods and dyskinesia in late PD 3 Since secondary effects such as confusion and hallucinations are not rare patients under apomorphine treatment should be closely monitored 3 Apomorphine can be administered by subcutaneous injection using a small pump which is carried by the patient A low dose is automatically administered throughout the day reducing the fluctuations of motor symptoms by providing a steady dose of dopaminergic stimulation After an initial apomorphine challenge in hospital to test its effectiveness and brief patient and primary caregiver often a spouse or partner the latter of whom takes over maintenance of the pump The injection site must be changed daily and rotated around the body to avoid the formation of nodules Apomorphine is also available in a more acute dose as an autoinjector pen for emergency doses such as after a fall or first thing in the morning Nausea and vomiting are common and may require domperidone an antiemetic medical citation needed In a study evaluating the efficacy of dopamine agonists compared to levodopa the results showed patients who took dopamine agonists were less likely to develop dyskinesia dystonia and motor fluctuations although were more likely to discontinue therapy due to negative side effects such as nausea edema constipation etc medical citation needed MAO B inhibitors Edit Monoamine oxidase inhibitors selegiline and rasagiline increase the level of dopamine in the basal ganglia by blocking its metabolization They inhibit monoamine oxidase B MAO B which breaks down dopamine secreted by the dopaminergic neurons Therefore reducing MAO B results in higher quantities of L DOPA in the striatum 3 Similarly to dopamine agonists MAO B inhibitors improve motor symptoms and delay the need of taking levodopa when used as monotherapy in the first stages of the disease but produce more adverse effects and are less effective than levodopa Evidence on their efficacy in the advanced stage is reduced although it points towards them being useful to reduce fluctuations between on and off periods 3 Although an initial study indicated selegiline in combination with levodopa increased the risk of death this has been later disproven 3 Metabolites of selegiline include L amphetamine and L methamphetamine not to be confused with the more potent dextrorotary isomers This might result in side effects such as insomnia Another side effect of the combination can be stomatitis Unlike other nonselective monoamine oxidase inhibitors tyramine containing foods do not cause a hypertensive crisis medical citation needed Other drugs Edit Some evidence indicates other drugs such as amantadine and anticholinergics may be useful as treatment of motor symptoms in early and late PD but since the quality of evidence on efficacy is reduced they are not first choice treatments 3 In addition to motor symptoms PD is accompanied by a range of different symptoms Different compounds are used to improve some of these problems 10 11 Examples are the use of clozapine for psychosis cholinesterase inhibitors for dementia modafinil for day somnolence and atomoxetine for executive dysfunction 10 11 12 A preliminary study indicates taking donepezil Aricept may help prevent falls in people with Parkinson s Donepezil boosts the levels of the neurotransmitter acetylcholine and is currently an approved therapy for the cognitive symptoms of Alzheimer s disease 13 In the study participants taking donepezil experienced falls half as often as those taking a placebo and those who previously fell the most showed the most improvement 14 The introduction of clozapine Clozaril represents a breakthrough in the treatment of psychotic symptoms of PD Prior to its introduction treatment of psychotic symptoms relied on reduction of dopamine therapy or treatment with first generation antipsychotics all of which worsened motor function Other atypical antipsychotics useful in treatment include quetiapine Seroquel ziprasidone Geodon aripiprazole Abilify and paliperidone Invega Clozapine is believed to have the highest efficacy and lowest risk of extrapyramidal side effect 12 Getting medication on time Edit Parkinson s patients who do not get the correct medicine at the right time when they are in hospital frequently they are in hospital due to unrelated illnesses sometimes cannot talk or walk The health of a majority deteriorated due to unsatisfactory medication management when they are in hospital Parkinson s UK believes the NHS could save up to 10m a year and improve the care of Parkinson s patients if mandatory training is introduced for all hospital staff 15 Parkinson UK found Nearly two thirds of people who have Parkinson s don t always get their medication on time in hospital More than three quarters of people with Parkinson s that we asked reported that their health deteriorated as a result of poor medication management in hospital Only 21 of respondents told us they got their medication on time without having to remind hospital staff 16 Surgery Edit Illustration showing an electrode placed deep seated in the brain Treating PD with surgery was once a common practice but after the discovery of levodopa surgery was restricted to only a few cases 17 Studies in the past few decades have led to great improvements in surgical techniques and surgery is again being used in people with advanced PD for whom drug therapy is no longer sufficient 17 Less than 10 of those with PD qualify as suitable candidates for a surgical response The three different mechanisms of surgical response for PD are ablative surgery the irreversible burning or freezing of brain tissue stimulation surgery or deep brain stimulation DBS and transplantation or restorative surgery 18 Target areas for DBS or lesions include the thalamus the globus pallidus the lesion technique being called pallidotomy or the subthalamic nucleus 17 Neuroablative lesion surgery Edit Neuroablative lesion surgery locates and destroys by heat the parts of the brain associated with producing Parkinsonian neurological symptoms The procedures generally involve a thalamotomy and or pallidotomy A thalamotomy is the destruction of a part of the thalamus in particular the ventralis intermedius to suppress tremor in 80 90 of patients If rigidity and akinesia are apparent the subthalamis nucleus is then the site of ablation A pallidotomy involves the destruction of the globus pallidus in particular the globus pallidus interna in patients with Parkinson s who have rigidity and akinesia Because it is difficult to accurately measure the amount of tissue to be destroyed tremors not uncommonly persist through multiple courses of surgery since tissue is irreversibly damaged and removed and testing smaller areas of tissue is safer to prevent serious complications such as a stroke or paralysis citation needed This method has been generally replaced by deep brain surgery Deep brain stimulation Edit Deep brain stimulation DBS is presently the most used method of surgical treatment because it does not destroy brain tissue it is reversible and it can be tailored to individuals at their particular stage of disease DBS employs three hardware components a neurostimulator also called an implanted pulse generator IPG which generates electrical impulses used to modulate neural activity a lead wire which directs the impulses to a number of metallic electrodes towards the tip of the lead near the stimulation target and an extension wire that connects the lead to the IPG The IPG which is battery powered and encased in titanium is traditionally implanted under the collarbone and is connected by the subcutaneous extension to the lead which extends from outside the skull under the scalp down into the brain to the target of stimulation The IPG or the entire three component system are sometimes referred to as a brain pacemaker due to the precedence and renown of cardiac pacemakers and similarities in the components of both types of systems medical citation needed The preoperative targeting of proper implantation sites can be accomplished by the indirect and direct methods The indirect method uses computer tomography magnetic resonance imaging or ventriculography to locate the anterior and posterior commissures and then employs predetermined coordinates and distances from the intercommissural line to define the target area Subsequent histologically defined atlas maps can also be used to verify the target area The direct method provides visualization and targeting of deep nuclei by applying stereotactic preoperative MRI which unlike the indirect method takes into account the anatomic variation of the nuclei s size position and functional segregation amongst individuals 19 Electrophysial functional mapping a tool used in both methods to verify the target nuclei has come under scrutiny due to its associated risks of hemorrhages dysarthria or tetanic contractions Recently susceptibility weighted imaging a type of MRI has shown incredible power in its ability to distinguish these deep brain nuclei and is being used in DBS to reduce the overuse of EFM 20 DBS is recommended to PD patients without important neuropsychiatric contraindications who have motor fluctuations and tremor badly controlled by medication or to those who are intolerant to medication 4 DBS is effective in suppressing symptoms of PD especially tremor A recent clinical study led to recommendations on identifying which Parkinson s patients are most likely to benefit from DBS 4 Diet EditSee also Dietary management of Parkinson s disease Muscles and nerves that control the digestive process may be affected by PD so it is common to experience constipation and gastroparesis food remaining in the stomach for a longer period of time than normal 21 A balanced diet is recommended to help improve digestion Diet should include high fiber foods and plenty of water 21 Levodopa and proteins use the same transportation system in the intestine and the blood brain barrier competing between them for access 21 When taken together the consequences of such competition is a reduced effectiveness of the drug 21 Therefore when levodopa is introduced excessive proteins are discouraged while in advanced stages additional intake of low protein products such as bread or pasta is recommended for similar reasons 21 To minimize interaction with proteins levodopa is recommended to be taken 30 minutes before meals 21 At the same time regimens for PD restrict proteins during breakfast and lunch and are usually taken at dinner 21 As the disease advances dysphagia may appear In such cases specific measures include the use of thickening agents for liquid intake special postures when eating and gastrostomy in the worst cases 21 Rehabilitation EditThis article has multiple issues Please help improve it or discuss these issues on the talk page Learn how and when to remove these template messages This article needs more medical references for verification or relies too heavily on primary sources Please review the contents of the article and add the appropriate references if you can Unsourced or poorly sourced material may be challenged and removed Find sources Management of Parkinson s disease news newspapers books scholar JSTOR February 2021 This article needs to be updated Please help update this article to reflect recent events or newly available information February 2021 Learn how and when to remove this template message Studies of rehabilitation in Parkinson s disease are scarce and are of low quality 22 23 Partial evidence indicates speech or mobility problems can improve with rehabilitation 22 23 Regular physical exercise and or therapy can be beneficial to maintain and improve mobility flexibility strength gait speed and quality of life 23 Exercise may also improve constipation Exercise interventions have been shown to benefit patients with Parkinson s disease in regards to physical functioning health related quality of life and balance and fall risk In a review of 14 studies examining the effects of exercise on persons with Parkinson s disease no adverse events or side effects occurred following any of the exercise interventions 24 Five proposed mechanisms by which exercise enhances neuroplasticity are known Intensive activity maximizes synaptic plasticity complex activities promote greater structural adaptation activities that are rewarding increase dopamine levels and therefore promote learning relearning dopaminergic neurones are highly responsive to exercise and inactivity use it or lose it and where exercise is introduced at an early stage of the disease progression can be slowed 21 25 One of the most widely practiced treatments for speech disorders associated with Parkinson s disease is the Lee Silverman voice treatment LSVT which focuses on increasing vocal loudness and has an intensive approach of one month 22 26 Speech therapy and specifically LSVT may improve voice and speech function 22 Occupational therapy OT aims to promote health and quality of life by helping people with the disease to participate in as many activities of their daily living as possible 22 Few studies have been conducted on the effectiveness of OT and their quality is poor although some indication shows it may improve motor skills and quality of life for the duration of the therapy 22 27 For monitoring patients with Parkinson s disease research teams are examining whether virtual house calls can replace visits to clinical facilities In a trial of such video visits patients preferred the remote specialist after 1 year 28 The home care was considered convenient but requires access to and familiarity with Internet enabled technologies Exercise Edit Regular physical exercise with or without physiotherapy can be beneficial to maintain and improve mobility flexibility strength gait speed and quality of life 23 29 Parkinson s Disease often causes sedentary behaviours resulting in lower quality of life in the long term 30 In terms of improving flexibility and range of motion for patients experiencing rigidity generalized relaxation techniques such as gentle rocking have been found to decrease excessive muscle tension Other effective techniques to promote relaxation include slow rotational movements of the extremities and trunk rhythmic initiation diaphragmatic breathing and meditation techniques 31 Common changes in gait associated with the disease such as hypokinesia slowness of movement shuffling and decreased arm swing are addressed by a variety of strategies to improve functional mobility and safety Goals with respect to gait during rehabilitation programs include improving gait speed base of support stride length trunk and arm swing movement Strategies include utilizing assistive equipment pole walking and treadmill walking verbal cueing manual visual and auditory exercises marching and PNF patterns and varying environments surfaces inputs open vs closed 32 Strengthening exercises have led to improvements in strength and motor functions in patients with primary muscular weakness and weakness related to inactivity in cases of mild to moderate Parkinson s disease 29 Patients perform exercises when at their best 45 minutes to one hour after medication 33 An 8 week resistance training study geared towards the lower legs found that patients with Parkinson s Disease gained abdominal strength and improved in their stride length walking velocity and postural angles 34 Also due to the forward flexed posture and respiratory dysfunctions in advanced Parkinson s disease deep diaphragmatic breathing exercises are beneficial for improving chest wall mobility and vital capacity 35 Exercise may correct constipation 36 Exercise training on a vibratory platform also called whole body vibration WBV training has been recently introduced as a training tool complementing standard physical rehabilitation programs for people with Parkinson s disease Compared to no intervention single sessions of WBV have resulted in improved motor ability as reflected by Unified Parkinson s Disease Rating Scale UPDRS tremor and rigidity scores 37 38 However longer term 3 5 weeks WBV programs have not led to improved UPDRS motor scores compared to conventional exercises 39 40 Furthermore multiple sessions of WBV have failed to enhance mobility measures i e the Timed Up and Go Test and 10 Meter Walking Test in people with Parkinson s disease 39 40 A recent review deemed that the evidence of the effects of WBV training on sensorimotor and functional performance remains inconclusive 41 Psychological treatments Edit Psychological treatment is based on cognitive behavioral interventions Cognitive behavioral therapy is confirmed as efficient for treatment of parkinsonian pain insomnia anxiety depression and impulse control disorders 42 Treating Parkinson s disease engages a multidisciplinary approach and includes a psychologist because motor symptoms can be worsened by psychosocial factors like anxiety phobia and panic attacks 42 Psychological treatment is tailored to each individual based on clinical recommendations especially if they have severe motor disability or cognitive problems Gait training Edit Patients with Parkinson s disease have an altered gait There is a reduced gait speed and step length increased axial rigidity and impaired rhythmicity These gait problems worsen as the disease continues This is a major disease burden that markedly affects independence and quality of life 43 Since it is proven that tremor dominant and akinetic rigid types of Parkinson s disease have various different visuomotor deficiencies like problems in visual perception and motor coordination that can influence their gait training it is recommended for them to receive neuropsychological assessment before physical therapy 44 Task specific gait training may also lead to long term gait improvement for patients with Parkinson s disease Previous research studies have utilized body weight support systems during gait training where individuals are suspended from an overhead harness with straps around the pelvic girdle as they walk on a treadmill This form of gait training has been shown to improve long term walking speed and a shuffling gait following a one month intervention period 45 Studies are also looking at the effect of tai chi on gait performance and balance in people with Parkinson s Disease 46 47 The first study concluded that tai chi was ineffective since there was no improvement on gait performance and no improvement on the Part III score of the Unified Parkinson s Disease Rating Scale UPDRS 46 The second study found that patients taking tai chi improved on their UPDRS score Timed Up and Go test six minute walk and backwards walking 47 It did not however show any improvements on their forward walking or their one leg stance test 47 Speech and occupational therapy Edit One of the most widely practiced treatments for speech disorders associated with Parkinson s disease is the Lee Silverman voice treatment LSVT 22 26 Speech therapy and specifically LSVT may improve speech 22 People with Parkinson s disease can develop dysarthria which is characterized by reduced speech intelligibility Prosodically based treatments may help 48 Occupational therapy aims to promote health and quality of life by helping people with the disease to participate in as much of their daily routine as possible 22 There is indication that occupational therapy may improve motor skills and quality of life for the duration of the therapy 22 27 Rhythmic auditory stimulation Edit Rhythmic auditory stimulation RAS is a neurological rehabilitation technique consisting in compensating the loss of motor regulation through an external sensory stimulation mediated by the sound This technique relies on the strong interaction between auditory and motor neural system By synchronizing his footsteps on the emitted sound that can be metronome like cues or complex music the patient can improves his gait speed and his stride length 49 Telemedicine Edit A 2017 one year randomized controlled trial found that providing remote neurologic care to individuals with Parkinson s Disease in their own homes was feasible and as effective as in person care While it can be more difficult for remote caregivers to establish trust while providing remote care that assessment of video visits in a patient s home found that after four virtual visits over one year individuals with Parkinson s Disease preferred their connection with the remote specialist to their local clinician 50 Benefits of telemedicine include convenience and cost effectiveness as the virtual in home visits have been found to reduce travel costs and time for patients relative to in office visits Some studies have found that the technology supports personalized connections similar to the house calls of the past Five randomized controlled trials indicated that quality of life was similar or improved for those receiving telemedicine care 50 51 Challenges related to telemedicine in treatment of individuals with Parkinson s Disease are related to the technological requirements as patients and their friends or families must have access to and familiarity with Internet based technologies 52 In part because of these technological requirements studies in the United States have tended to include few participants from ethnic minorities and disproportionately include more highly educated populations One solution proposed to reduce social and economic barriers to access to remote care is to establish satellite teleneurology clinics in underserved regions 51 50 Physicians cite barriers with inability to perform a full neurologic exam in addition to technology and reimbursement issues 53 New telemedicine technologies being used or evaluated in the context of telemedicine include proprietary wearables self sensing and adjusting closed loop systems robotic technologies smart devices to detect movements programs to improve medication adherence smart home integration and artificial intelligence or machine learning based systems 54 Palliative care EditPalliative care is often required in the final stages of the disease often when dopaminergic treatments have become ineffective The aim of palliative care is to achieve the maximum quality of life for the person with the disease and those surrounding him or her Some central issues of palliative are caring for patients at home while adequate care can be given there reducing or withdrawing dopaminergic drug intake to reduce drug side effects and complications preventing pressure ulcers by management of pressure areas of inactive patients and facilitating the patient s end of life decisions for the patient as well as involved friends and relatives 55 Other treatments EditRepetitive transcranial magnetic stimulation temporarily improves levodopa induced dyskinesias 56 Its full usefulness in PD is an open research field 57 Different nutrients have been proposed as possible treatments however no evidence shows vitamins or food additives improve symptoms 58 Not enough evidence exists to suggest that acupuncture and practice of qigong or t ai chi have any effect on symptoms 59 60 61 Fava and velvet beans are natural sources of L DOPA and are taken by many people with PD While they have shown some effectiveness 62 their intake is not free of risks Life threatening adverse reactions have been described such as the neuroleptic malignant syndrome 63 64 Faecal transplants may have a beneficial impact on symptoms 65 History Edit An 1893 photograph of Jean Martin Charcot who made important contributions to the understanding of the disease including the proposal of anticholinergics as treatments for tremor The positive albeit modest effects of anticholinergic alkaloids obtained from the plant of the belladonna were described during the 19th century by Charcot Erb and others Modern surgery for tremor consisting of the lesioning of some of the basal ganglia structures was first tried in 1939 and was improved over the following 20 years 66 Before this date surgery consisted in lesioning the corticospinal pathway with paralysis instead of tremor as result Anticholinergics and surgery were the only treatments until the arrival of levodopa which reduced their use dramatically 66 67 Levodopa was first synthesized in 1911 by Casimir Funk but it received little attention until the mid 20th century 68 It entered clinical practice in 1967 and the first large study reporting improvements in people with Parkinson s disease resulting from treatment with levodopa was published in 1968 Levodopa brought about a revolution in the management of PD 68 69 By the late 1980s deep brain stimulation emerged as a possible treatment and it was approved for clinical use by the FDA in 1997 70 Research directions EditSee also Parkinson s disease clinical research No new PD treatments are expected in the short term but several lines of research are active for new treatments 71 Such research directions include the search of new animal models of the disease and the potential usefulness of gene therapy stem cells transplants and neuroprotective agents 72 Animal models Edit The tragedy of a group of drug addicts in California in the early 1980s who consumed a contaminated and illicitly produced batch of the synthetic opiate MPPP brought to light MPTP as a cause of parkinsonian symptoms 73 Other predominant toxin based models employ the insecticide rotenone the herbicide paraquat and the fungicide maneb 74 Models based on toxins are most commonly used in primates Transgenic rodent models also exist 75 Gene therapy Edit This section relies excessively on references to primary sources Please improve this section by adding secondary or tertiary sources Find sources Management of Parkinson s disease news newspapers books scholar JSTOR December 2016 Learn how and when to remove this template message Main article Gene therapy in Parkinson s disease Present treatments of Parkinson s disease provide satisfactory disease control for most early stage patients 76 However present gold standard treatment of PD using levodopa is associated with motor complications and does not prevent disease progression 76 More effective and long term treatment of PD are urgently needed to control its progression 76 In vivo gene therapy is a new approach for treatment of PD 77 The use of somatic cell gene transfer to alter gene expression in brain neurochemical systems is a novel alternative conventional treatment 77 Gene therapy is currently under investigation 72 78 It involves the use of a noninfectious virus to shuttle a gene into a part of the brain The gene used leads to the production of an enzyme which helps to manage PD symptoms or protects the brain from further damage 72 One of the gene therapy based approach involves gene delivery of neurturin and glial cell line derived neurotrophic factor GDNF to the putamen in patients with advanced Parkinson s disease 76 GDNF protects dopamine neurons in vitro and animal models of parkinsonism neurturin is a structural and functional analogue of GDNF that protected dopamine neuron in animal model of the disease 76 Despite open label trials showing benefits of continuous infusion of GDNF the results were not confirmed in double blind studies 76 This may be due to the distribution factor the trophic factor was not distributed sufficiently throughout the target place 76 Another gene therapy of PD involved insertion of the glutamic acid decarboxylase GAD into the subthalamic nucleus 77 GAD enzyme controls GABA productions 77 In Parkinson s disease the activity of both GABA efferents to the subthalamic nucleus and its target within the basal ganglia circuitry are affected 77 This strategy used adeno associated viral vector AAV2 to deliver GAD to the subthalamic nucleus 77 The trial was done to compare the effect of bilateral delivery of AAV2 GAD into the subthalamic nucleus with bilateral sham surgery in patients with advanced Parkinson s disease 77 The study showed the first success of randomised double blind gene therapy trial for a neurodegenerative disease and justified the continued development of AAV2 GAD for treatment of PD 77 Neuroprotective treatments Edit While several chemical compounds such as GNDF chemical structure pictured have been proposed as neuroprotectors in PD none has proven its efficacy Investigations on neuroprotection are at the forefront of PD research Currently no proven neuroprotective agents or treatments are available for PD While still theoretical neuroprotective therapy is based on the idea that certain neurons that produce dopamine and are susceptible to premature degeneration and cell death can be protected by the introduction of neuroprotective pharmaceuticals This protection can occur before any symptoms manifest based on genetic risk and also during early or late stage PD when other treatments have ceased their impact due to the progression of the disease Accordingly neuroprotective therapy seeks to delay the introduction of levodopa Several molecules have been proposed as potential treatments 72 However none of them has been conclusively demonstrated to reduce degeneration 72 Agents currently under investigation include antiapoptotics omigapil CEP 1347 antiglutamatergics monoamine oxidase inhibitors selegiline rasagiline promitochondrials coenzyme Q10 creatine calcium channel blockers isradipine and growth factors GDNF 72 Preclinical research also targets alpha synuclein 71 Selegiline Edit Selegiline is in a group of medications called monoamine oxidase type B MAO B inhibitors 79 Selegiline is used to help control the symptoms of Parkinson s disease in people who are taking levodopa and carbidopa combination Sinemet Selegiline may help people with PD by stopping the effects of levodopa carbidopa from wearing off and increasing the length of time levodopa carbidopa continues to control symptoms Rasagiline Edit In response to potentially toxic amphetamine metabolites caused by selegiline another promising treatment is in MAO B propargyl amine inhibitor rasagiline N propargyl 1 R aminoindan Azilect R The oral bioavailability of rasagiline is 35 it reaches T max after 0 5 1 0 hours and its half life is 1 5 3 5 hours Rasagiline undergoes extensive hepatic metabolism primarily by cytochrome P450 type 1A2 CYP1A2 Rasagiline is initiated at 1 mg once daily dose as monotherapy in early PD patients and at 0 5 1 0 mg once daily as adjunctive to levodopa in advanced PD patients 80 Neural transplantation Edit Since early in the 1980s fetal porcine carotid or retinal tissues have been used in cell transplants for PD patients 72 Although there was initial evidence of mesencephalic dopamine producing cell transplants being beneficial the best constructed studies up to date indicate that cell transplants have no effect 72 An additional significant problem was the excess release of dopamine by the transplanted tissue leading to dystonias 81 Stem cell transplants are a main research recent target they are easy to manipulate and when transplanted into the brains of rodents and monkeys cells survive and improve behavioral abnormalities of the animals 72 82 Nevertheless use of fetal stem cells is controversial 72 Some have proposed that such controversy may be overcome with the use of induced pluripotent stem cells from adults 72 References Edit Medications amp Treatments Parkinson s Disease Foundation PDF Archived from the original on 2016 11 24 Retrieved 2009 11 12 Medications for Parkinson s Disease What s on the Horizon Parkinson s Disease Foundation PDF Archived from the original on 2009 12 18 Retrieved 2009 11 12 a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag The National Collaborating Centre for Chronic Conditions ed 2006 Symptomatic pharmacological therapy in Parkinson s disease Parkinson s Disease London Royal College of Physicians pp 59 100 ISBN 978 1 86016 283 1 Guidance was reviewed in 2011 and no changes were made According to NICE as of July 2014 a revised guidance was under development with anticipated publication in 2017 a b c Bronstein JM Tagliati M Alterman RL et al October 2010 Deep Brain Stimulation for Parkinson Disease An Expert Consensus and Review of Key Issues Arch Neurol 68 2 165 65 doi 10 1001 archneurol 2010 260 PMC 4523130 PMID 20937936 a b Ceravolo R Frosini D Rossi C Bonuccelli U December 2009 Impulse control disorders in Parkinson s disease definition epidemiology risk factors neurobiology and management Parkinsonism Relat Disord 15 Suppl 4 S111 15 doi 10 1016 S1353 8020 09 70847 8 PMID 20123548 Morelli Micaela Blandini Fabio Simola Nicola Hauser Robert A 2012 A2AReceptor Antagonism and Dyskinesia in Parkinson s Disease Parkinson s Disease 2012 489853 doi 10 1155 2012 489853 ISSN 2090 8083 PMC 3382949 PMID 22754707 Armentero Marie Therese Pinna Annalisa Ferre Sergi Lanciego Jose Luis Muller Christa E Franco Rafael December 2011 Past present and future of A2A adenosine receptor antagonists in the therapy of Parkinson s disease Pharmacology amp Therapeutics 132 3 280 299 doi 10 1016 j pharmthera 2011 07 004 ISSN 0163 7258 PMC 3205226 PMID 21810444 Goldenberg MM October 2008 Medical management of Parkinson s disease P amp T 33 10 590 606 PMC 2730785 PMID 19750042 a b c d Samii A Nutt JG Ransom BR May 2004 Parkinson s disease Lancet 363 9423 1783 93 doi 10 1016 S0140 6736 04 16305 8 PMID 15172778 S2CID 35364322 a b Warner Carly B Ottman Andreina A Brown Jamie N December 2018 The Role of Atomoxetine for Parkinson Disease Related Executive Dysfunction A Systematic Review Journal of Clinical Psychopharmacology 38 6 627 631 doi 10 1097 JCP 0000000000000963 ISSN 1533 712X PMID 30346335 S2CID 53046069 a b The National Collaborating Centre for Chronic Conditions ed 2006 Non motor features of Parkinson s disease Parkinson s Disease London Royal College of Physicians pp 113 33 ISBN 978 1 86016 283 1 a b Hasnain M Vieweg WV Baron MS Beatty Brooks M Fernandez A 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Barichella M Cereda E Pezzoli G October 2009 Major nutritional issues in the management of Parkinson s disease Mov Disord 24 13 1881 92 doi 10 1002 mds 22705 hdl 2434 67795 PMID 19691125 S2CID 23528416 a b c d e f g h i j The National Collaborating Centre for Chronic Conditions ed 2006 Other key interventions Parkinson s Disease London Royal College of Physicians pp 135 46 ISBN 978 1 86016 283 1 a b c d Goodwin VA Richards SH Taylor RS Taylor AH Campbell JL April 2008 The effectiveness of exercise interventions for people with Parkinson s disease a systematic review and meta analysis Mov Disord 23 5 631 40 doi 10 1002 mds 21922 hdl 10871 17451 PMID 18181210 S2CID 3808899 Goodwin V A Richards S H Taylor R S Taylor A H Campbell J L 2008 The effectiveness of exercise interventions for people with Parkinson s disease a systematic review and meta analysis Movement Disorders 23 5 631 40 doi 10 1002 mds 21922 hdl 10871 17451 PMID 18181210 S2CID 3808899 a href Template Cite journal html title 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PMID 20155994 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Selegiline Information MedLine Plus Retrieved on 2010 02 02 Treat Parkinson Disease Effectively Archived 2010 02 08 at the Wayback Machine Retrieved on 2010 02 02 Redmond DE October 2002 Cellular replacement therapy for Parkinson s disease where we are today The Neuroscientist 8 5 457 88 doi 10 1177 107385802237703 PMID 12374430 Stem Cell Research Aims to Tackle Parkinson s Disease Retrieved 2010 04 16 External links EditParkinson s Medication Chart at the Parkinson s Disease Foundation PDtrials Find What Treatments Are Possible Retrieved from https en wikipedia org w index php title Management of Parkinson 27s disease amp oldid 1129452577 Medication, wikipedia, wiki, book, books, library,

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