Hereditary Coproporphyria

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Background

Hereditary coproporphyria is one of the porphyrias, a group of diseases that involves defects in heme metabolism and that results in excessive secretion of porphyrins and porphyrin precursors. Inheritance is autosomal (usually autosomal dominant, but sometimes autosomal recessive).

Many persons with the disorder remain asymptomatic. Attacks may be triggered by chemicals (including many medications) or situations (eg, fasting) that boost heme synthesis. Coproporphyria manifests with signs and symptoms that include abdominal pain, neuropathies, constipation, and skin changes.

Pathophysiology

Coproporphyria is an autosomal dominant disease that results from defects in the enzyme coproporphyrinogen oxidase. This enzyme speeds the conversion of coproporphyrinogen to protoporphyrinogen. In coproporphyria, the porphyrin precursors porphobilinogen and amino-levulinic acid (ALA) accumulate, as well as the formed porphyrin coproporphyrin. The predominant problem is neurologic damage that leads to peripheral and autonomic neuropathies and the psychiatric manifestations. In coproporphyria, skin disease also is present but not as commonly as the neurovisceral symptoms.

The etiology of the skin disease may be the deposition of formed porphyrins in the skin that react with sunlight and lead to skin damage. Although patients with acute neurovisceral attacks always have elevations of porphobilinogen and ALA, researchers still are unclear about how this leads to the symptomatic disease because most patients with the genetic defect have excessive porphyrin secretion but no symptoms.[1]

Epidemiology

Frequency

United States

Coproporphyria is 20 times less common (ie, 1-4 cases per 1,000,000 people) than acute intermittent porphyria (AIP).

Mortality/Morbidity

Researchers feel that coproporphyria is a less severe disease than AIP, but deaths have been reported in improperly treated cases.

Sex- and Age-based Demographics

Researchers feel that women with coproporphyria tend to be symptomatic more than men are, but the data are sparse.

Most patients with porphyria become symptomatic at age 18-40 years. Attacks are rare before puberty or after age 40 years.

History

Coproporphyria has neurovisceral, psychiatric, neurologic, and skin manifestations. The usual sequence of events in acute attacks is abdominal pain, then psychiatric symptoms (eg, hysteria), then peripheral neuropathies. The exact mechanism by which the porphyrin precursors lead to these symptoms is unknown.

Neurovisceral manifestations

Neurovisceral signs and symptoms consist of autonomic neuropathies such as constipation, abdominal pain, and vomiting. Patients can have very severe abdominal pain that lasts for several days. Pain of short duration (minutes) or chronic abdominal pain does not develop in coproporphyria. The pain often is epigastric and is colicky in nature.

Patients often are free of pain between attacks. Constipation is common and can be very severe. Nausea and vomiting frequently are present.

Neurologic manifestations

Patients with coproporphyria can have both central nervous system (CNS) and peripheral nervous system manifestations. CNS manifestations include seizures, mental status changes, cortical blindness, and coma. Peripheral neuropathies are predominantly motor neuropathies and can mimic Guillain-Barré syndrome. The weakness usually starts in the lower limbs and ascends, but neuropathies occur in any nerve distribution.

Diffuse pain, especially in the upper body, can be observed. Patients also can develop autonomic neuropathies, including hypertension and tachycardia.

Psychiatric manifestations

Patients can have a wide variety of psychiatric symptoms. Depression is common. Patients with psychiatric manifestations usually have concurrent neurologic or abdominal symptoms.

Skin manifestations

The skin disease is similar to porphyria cutanea tarda. With long-term (not acute) sun exposure, patients can develop vesicles and bullae. If patients are symptomatic with coproporphyria, they tend to have neurovisceral symptoms rather than skin symptoms. Blisters form in sun-exposed areas and can evolve into chronic scarred areas of fragile skin. Patients also may develop excessive hair growth in sun-exposed areas.

Causes

Like AIP, coproporphyria is due to a combination of a genetic enzyme defect and acquired causes that become symptomatic in rare cases.[2] In patients with coproporphyria, the function of coproporphyrinogen oxidase is only 40-60% of normal.[3] Also, like AIP, most patients with defects in coproporphyrinogen oxidase never have any symptoms. The classic inducers of porphyria are chemicals or situations that boost heme synthesis. This includes fasting and many medications.

Although extensive lists of safe and unsafe drugs exist, many of these are based on anecdotes or laboratory evidence rather than meeting strict criteria. In general, drugs that lead to increased activity of the hepatic P450 system (eg, phenobarbital, sulfonamides, estrogens, alcohol) are associated with porphyria attacks. A large and detailed list, shown below, is available through the European Porphyria Network. Fasting for several days also can trigger an attack. Many attacks will occur, however, without any obvious provocation.

Haimowitz and collegues reported a case of cholestatic liver failure due in a patient with undiagnosed HCP after the use of Hydroxycut™, an over-the-counter supplement containing Camellia sinensis and hydroxycitric acid. This case highlights the genetic susceptibility of the disease that can be incited by environmental exposures.[4]

Table 1. Drugs Thought Safe in Porphyria*



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Table 2. Drugs Thought Unsafe in Porphyria



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Physical Examination

Vital signs are as follows:

Neurologic manifestations are as follows:

Abdominal examination: Despite the intense pain that may accompany a severe attack, the findings on abdominal examination often are nonspecific.

Skin manifestations are as follows:

Approach Considerations

The diagnosis of hereditary coproporphyria is established by demonstrating excess secretion of coproporphyrins in the stool.[5] Levels of stool coproporphyrins, especially coproporphyrin type III, are markedly elevated, usually 10-200 times greater than in controls.

Levels of urine porphyrins vary, but urine coproporphyrin levels usually are also markedly elevated, especially during acute attacks of the disease. Elevated porphobilinogen levels in the presence of appropriate clinical symptoms is diagnostic of porphyria; this is true of both hereditary coproporphyria and acute intermittent porphyria (AIP).[7, 8] After symptom resolution, urinary porphobilinogen levels may return to normal relatively quickly.[8]

Mild elevations of urine coproporphyrins (eg, as high as two times the reference range) are common and nonspecific. Fasting, subtle liver disease, or normal variations are the most common causes of elevated urine coproporphyrins. In such cases, patients may be incorrectly labeled as having porphyria.

Serum sodium levels should be measured in patients experiencing attacks, as hyponatremia is common; this has been attributed to the syndrome of inappropriate secretion of antidiuretic hormone (SIADH), but renal and/or gastrointestinal sodium loss may also be involved.[8] Mild leukocytosis is another nonspecific finding during an attack.

Although coproporphyria is caused by a defective enzyme, there is little use in measuring the activity of coproporphyrinogen oxidase. The vast majority of patients who have the defective enzyme do not have any symptoms of the disease. Furthermore, the only available clinical assay has been withdrawn due to problems with high rates of false-positive results. The diagnosis of a porphyria attack rests on demonstration of excessive excretion of porphyrins and porphyrin precursors.

Imaging studies are not helpful. Abdominal films sometimes demonstrate an ileus. Findings on cranial computed tomography scans are normal. Brain magnetic resonance imaging scans occasionally show signs of increased edema in patients with very severe attacks.

Identification of a heterozygous pathogenic variant in CPOX (encoding the enzyme coproporphyrinogen-III oxidase) confirms the diagnosis and enables family studies.[9]

Approach Considerations

The goals in managing an acute attack of porphyria are to decrease heme synthesis and to reduce the production of porphyrin precursors.[10, 11] For mild attacks (ie, mild pain and no vomiting, paralysis, or hyponatremia), guidelines from the advise that a high-carbohydrate diet (eg, with glucose-containing drinks and high-energy foods) and supportive measures may be used for up to 48 hours.[8]

High oral doses of glucose (400 g/d) can inhibit heme synthesis and are useful for the treatment of mild attacks. Intravenous glucose solutions (eg, 5% or 10% dextrose in water) can be used in patients who cannot eat, but may aggravate hyponatremia.

Treat severe attacks, especially those involving severe neurologic symptoms, with hematin at a dose of 4 mg/kg/d for 4 days. Patients with severe attacks should be hospitalized for symptom control and monitoring of fluid and electrolyte balance, as well as cardiovascular, respiratory, and neurologic function.[8]

Pain control is best achieved with narcotics; high doses are typically required. Administer laxatives and stool softeners with the narcotics to avert exacerbating the patient's constipation.

For seizure control, administer gabapentin. Most of the classic antiseizure medications are contraindicated in acute attacks of porphyria. However, the British and Irish Porphyria Network, while acknowledging that the safety of intravenous diazepam is controversial in porphyria attacks, concludes that benefit outweighs risk in this acute situation.[8]

Treatment options for other manifestations are as follows[8] :

Unlike porphyria cutanea tarda, the skin disease in coproporphyria does not respond to phlebotomy or antimalarial drugs.

Diet

Patients should receive a high-carbohydrate diet during the attack. Administer intravenous glucose if patients cannot eat. Between attacks, patients should eat a constant balanced diet rather than one that is extremely rich in glucose.

Medication Summary

The goals of pharmacotherapy are to reduce morbidity and to prevent complications. Panhematin is the drug of choice for severe attacks and may be used long-term for patients with recurrent attacks. Narcotics are used to control pain, and gabapentin is used to control seizures.

Panhematin (Hemin)

Clinical Context:  DOC for severe porphyria attacks. Enzyme inhibitor derived from processed red blood cells and an iron-containing metalloporphyrin. Was previously known as hematin, a term used to describe the chemical reaction product of hemin and sodium carbonate solution.

Class Summary

The key treatment of porphyria is stopping heme synthesis. Hematin provides negative feedback to the heme synthetic pathway and shuts down productions of porphyrins and porphyrin precursors.

Further Outpatient Care

Patients with recurrent attacks may benefit from a program of chronic hematin infusion. For example, women with severe symptoms at the time of their menses can have 1 dose of 4 mg/kg before the onset of their period.

Deterrence/Prevention

Avoid medicines that can provoke an attack. The list of medications to avoid is long (see Causes); however, only a few have been implicated clearly in porphyria. Patients also should avoid overconsumption of alcohol and avoid fasting.

Prognosis

See the list below:

Patient Education

See the list below:

Author

Thomas G DeLoughery, MD, Professor of Medicine, Pathology, and Pediatrics, Divisions of Hematology/Oncology and Laboratory Medicine, Associate Director, Department of Transfusion Medicine, Division of Clinical Pathology, Oregon Health and Science University School of Medicine

Disclosure: Nothing to disclose.

Specialty Editors

Francisco Talavera, PharmD, PhD, Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference

Disclosure: Received salary from Medscape for employment. for: Medscape.

Marcel E Conrad, MD, Distinguished Professor of Medicine (Retired), University of South Alabama College of Medicine

Disclosure: Partner received none from No financial interests for none.

Chief Editor

Emmanuel C Besa, MD, Professor Emeritus, Department of Medicine, Division of Hematologic Malignancies and Hematopoietic Stem Cell Transplantation, Kimmel Cancer Center, Jefferson Medical College of Thomas Jefferson University

Disclosure: Nothing to disclose.

Additional Contributors

Clarence Sarkodee Adoo, MD, FACP, Consulting Staff, Department of Bone Marrow Transplantation, City of Hope Samaritan BMT Program

Disclosure: Nothing to disclose.

References

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Acetazolamide acetylcholine



Actinomycin D



Acyclovir



Adenosine monophosphate



Adrenaline



Alclofenac



Allopurinol



Alpha tocopheryl



Acetate



Amethocaine



Amiloride



Aminocaproic acid



Aminoglycosides



Amoxicillin



Amphotericin



Ampicillin



Ascorbic acid



Aspirin



Atenolol



Atropine



Azathioprine



Beclomethasone



Benzhexol HCl



Beta-carotene



Biguanides



[Bromazepam]



Bromides



Buflomedil HCl



Bumetanide



Bupivacaine



Buprenorphine



Buserelin



Butacaine SO4



Canthaxanthin



Carbimazole



[Carpipramine HCl]



Chloral hydrate



[Chlormethiazole]



[Chloroquine]



[Chlorothiazide]



Chlorpheniramine



Chlorpromazine



Ciprofloxacin



Cisapride



Cisplatin



Clavulanic acid



Clofibrate



Clomiphene



Cloxacillin



Co-codamol



Codeine phosphate



Colchicine



[Corticosteroids]



Corticotrophin (adrenocorticotropic hormone [ACTH])



Coumarins



Cyclizine



Cyclopenthiazide



Cyclopropane



[Cyproterone acetate]



Danthron



Desferrioxamine



Dexamethasone



[Dextromoramide]



Dextrose



Diamorphine



Diazoxide



Dicyclomine HCl



Diflunisal



Digoxin



Dihydrocodeine



Dimercaprol



Dimethicone



Dinoprost



Diphenoxylate HCl



Dipyridamole



[Disopyramide]



Domperidone



Doxorubicin HCl



Droperidol



[Estazolam]



Ethacrynic acid



Ethambutol



[Ethinyl oestradiol]



Ethoheptazine citrate



Etoposide



Famotidine



Fenbufen



[Fenofibrate]



Fenoprofen



Fentanyl



Flucytosine



Flumazenil



Fluoxetine HCl



Flurbiprofen



Fluvoxamine



Maleate



Folic acid



Fructose



Fusidic acid



Follicle-stimulating hormone



Gentamicin



Glafenine



Glucagon



Glucose



Glyceryl trinitrate



Goserelin



Guanethidine



Guanfacine HCl



Haem arginate



[Haloperidol]



Heparin



Heptaminol HCl



Hexamine



[Hydrocortisone]



Ibuprofen



Indomethacin



Insulin



Iron



Josamycin



[Ketamine]



Ketoprofen



Ketotifen



Labetalol



Luteinizing hormone–releasing hormone



Liquorice



Lithium



Salts lofepramine



Loperamide



[Lorazepam]



Magnesium-sulphate



[Mebendazole]



Mecamylamine



Meclofenoxate HCl



Meclozine



Mefloquine HCl



[Melphalan]



Meptazinol



Mequitazine



Metformin



Methadone



[Methotrimeprazine]



Methylphenidate



Methyluracil



Metipropranolol



Metopimazine



Metoprolol



[Metronidazole]



[Midazolam]



Minaprine HCl



Minaxolone



Morphine



Nadolol



Naftidrofuryl



Oxalate



[Naproxen sodium]



Natamycin



Nefopam HCl



Neostigmine



Netilmicin



Niflumic acid



Nitrous oxide



Norfloxacin



Ofloxacin



Oxolinic acid



Oxybuprocaine



[Oxyphenbutazone]



Oxytocin



[Pancuronium bromide]



Paracetamol



Paraldehyde



Parapenzolate Br



Penicillamine



Penicillin



Pentolinium



Pericyazine



Pethidine



Phenformin



Phenoperidine



Phentolamine mesylate



Pipotiazine



Palmitate



Piracetam



Pirbuterol



Pirenzepine



Pizotifen



[Prazosin]



[Prednisolone]



Primaquine



Probucol



Procainamide HCl



Procaine



Prochlorperazine



Proguanil HCl



Promazine



Propantheline Br



Propofol



Propranolol



Propylthiouracil



[Proxymetacaine]



Pseudoephedrine HCl



Pyridoxine



[Pyrimethamine]



Quinidine



Quinine



[Ranitidine]



Reserpine



Resorcinol



Salbutamol



Senna



Sodium bromide



Sodium ethylenediaminetetraacetic acid



Sodium fusidate



Sorbitol



Streptomycin



Sulbutiamine



Sulindac



Sulfadoxine



Suxamethonium



Talampicillin



Temazepam



Tetracaine



[Tetracyclines]



Thiouracils



Thyroxine



Tiaprofenic acid



Ticarcillin



Tienilic acid



Timolol maleate



Tolazoline



Tranexamic acid



Triacetyloleandomycin



Triamterene



Triazolam



[Trichlormethiazide]



Trifluoperazine



Trimeprazine



Tartrate



Trimetazidine HCl



Tripelennamine



Tubocurarine



Vancomycin



[Vincristine]



Vitamins



Warfarin sodium



Zidovudine



Zinc Preparations



*Bracketed [] drugs are those in which experimental evidence of porphyrin genicity is conflicting.
Alcuronium



*Alphaxalone



Alphadolone



Alprazolam



Aluminium



Preparations



Amidopyrine



Aminoglutethimide



Aminophylline



Amiodarone



*Amitriptyline



[Amphetamines]



*Amylobarbitone



Antipyrine



*Auranofin



*Aurothiomalate



Azapropazone



Baclofen



*Barbiturates



*Bemegride



Bendrofluazide



Benoxaprofen



Benzbromarone



[Benzylthiouracil]



[Bepridil]



Bromocriptine



Busulphan



*Butylscopolamine



Captopril



*Carbamazepine



*Carbromal



*Carisoprodol



[Cefuroxime]



[Cephalexin]



[Cephalosporins]



[Cephradine]



[Chlorambucil]



*Chloramphenicol



*Chlordiazepoxide



*Chlormezanone



Chloroform



*Chlorpropamide



Cinnarizine



Clemastine



[Clobazam]



[Clomipramine HCl]



[Clonazepam]



Clonidine HCl



*Clorazepate



Cocaine



[Colistin]



Co-trimoxazole



Cyclophosphamide



Cycloserine



Cyclosporin



Danazol



*Dapsone



Dexfenfluramine



Dextropropoxyphene



Diazepam



*Dichloralphenazone



*Diclofenac Na



Dienoestrol



Diethylpropion



Dihydralazine



*Dihydroergotamine



Diltiazem



*Dimenhydrinate



*Diphenhydramine



[Dothiepin HCl]



Doxycycline



*Dydrogesterone



*Econazole NO3



*Enalapril



Enflurane



*Ergot compounds



Ergometrine maleate



Ergotamine tartrate



*Erythromycin



*Estramustine



Ethamsylate



*Ethanol



Ethionamide



*Ethosuximide



*Ethotoin



Etidocaine



Etomidate



Fenfluramine



*Flucloxacillin



*Flufenamic acid



Flunitrazepam



Flupenthixol



Flurazepam



*Frusemide



*Glibenclamide



*Glutethimide



*Glipizide



Gramicidin



*Griseofulvin



[Haloperidol]



*Halothane



*Hydantoins



*Hydralazine



*Hydrochlorothiazide



*Hydroxyzine



Hyoscine



*Imipramine



Iproniazid



Isometheptene mucate



[Isoniazid]



Kebuzone



Ketoconazole



*Levonorgestrel



Lignocaine



*Lisinopril



Loprazolam



Loxapine



*Lynestrenol



Lysuride



Maleate



Maprotiline HCl



Mebeverine HCl



*Mecillinam



*Medroxyprogesterone



[Mefenamic acid]



Megestrol acetate



*Mephenytoin



Mepivacaine



*Meprobamate



Mercaptopurine



Mercury compounds



Mestranol



[Metapramine HCl]



Methamphetamine



Methohexitone



Methotrexate



Methoxyflurane



Methsuximide



*Methyldopa



*Methylsulphonal



*Methyprylone



Methysergide



*Metoclopramide



Metyrapone



Mianserin HCl



Miconazole



[Mifepristone]



Minoxidil



*Nandrolone



*Nalidixic acid



Natamycin



*Nandrolone



[Nicergoline]



*Nifedipine



*Nikethamide



Nitrazepam



*Nitrofurantoin



Nordazepam



Norethynodrel



*Norethisterone



[Nortriptyline]



Novobiocin



*Oral contraceptives



*Orphenadrine



Oxanamide



[Oxazepam]



Oxybutynin HCl



Oxycodone



*Oxymetazoline



*Oxyphenbutazone



Oxytetracycline



Paramethadione



Pargyline



*Pentazocine



Perhexiline



Phenacetin



Phenelzine



*Phenobarbitone



Phenoxybenzamine



*Phensuximide



*Phenylbutazone



Phenylhydrazine



*Phenytoin



Pipebuzone



Pipemidic



Acid



Piritramide



*Piroxicam



*Pivampicillin



*Pivmecillinam



Prazepam



Prenylamine



*Prilocaine



*Primidone



[Probenecid]



*Progesterone



Progabide



Promethazine



[Propanidid]



*Pyrazinamide



Pyrrocaine



Quinalbarbitone



Rifampicin



Simvastatin



Sodium aurothiomalate



Sodium oxybate



[Sodium valproate]



*Spironolactone



Stanozolol



Succinimides



*Sulfacetamide



*Sulfadiazine



*Sulfadimidine



*Sulfadoxine



*Sulfamethoxazole



*Sulfasalazine



*Sulfonylureas



Sulfinpyrazone



Sulpiride



Sulthiame



Sultopride



*Tamoxifen



*Terfenadine



Tetrazepam



*Theophylline



*Thiopentone Na



Thioridazine



Tilidate



Tinidazole



*Tolazamide



*Tolbutamide



Tranylcypromine



Trazodone HCl



Trimethoprim



[Trimipramine]



Troxidone



Valproate



Valpromide



Veralipride



*Verapamil



*Vibramycin



Viloxazine HCl



[Vinblastine]



[Vincristine]



Zuclopenthixol



*These drugs have been associated with acute attacks of porphyria.



†Bracketed [] drugs are those in which experimental evidence of porphyringenicity is conflicting.