Over 140 different TTR gene mutations have been identified, but only some are associated with most ATTRv amyloidosis cases [4950]. Most mutations causing ATTRv amyloidosis are gain of function mutations with autosomal dominant inheritance. However, penetrance and expressivity are highly variable among the diverse variants, even within the same family [515253].

Genetic ATTR disease presents an age of onset ranging from the second to the ninth decade of life and p.Val50Met (previously designated Val30Met) is the most recognized TTR gene mutation [48] and the most prevalent genotype among all THAOS patients (49.6%). Its early onset phenotype, typically causing ATTR polyneuropathy (also referred to as familial amyloidosis polyneuropathy) has endemic focus in Portugal, Sweden, and Japan [48]. Other mutations, particularly those more commonly associated with ATTR-CM, manifest as late onset phenotypes. These include among others the late-onset form associated with the p.Val50Met mutation, and the p.Val142Ile mutation (previously designated V122I), which occurs more commonly in African-American, Western, African, and Hispanic populations, described with an estimated prevalence of 4% in the United States (US) [26].

The p.Ala117Ser TTR variant in China and Taiwan and the p.Thr80 Ala mutation, occurring mostly in patients of Irish descent [54] (and often manifesting as a mixed neuropathic and cardiomyopathic phenotype [26]) have been considered founder mutations in these regions [30].

Although the phenotypic heterogeneity of the disease contributes to challenging the diagnosis [54555657] some data from the THAOS analysis emerged regarding the genotype-phenotype relationship in what concerns the predominant cardiac, neurologic, or mixed phenotypes.

Wild-type ATTR-CM may have an onset at 60 to 65 years of age, although its prevalence increases at older ages, and it affects predominantly males [93166].

The prevalence of ATTRwt-CM is unknown, but it is surely much more frequent than previously thought, having been diagnosed in several clinical contexts involving the elderly as already mentioned [823676869707172737475]. ATTRwt patients can also develop neurologic complications including polyneuropathy [6676].

The median survival for untreated patients with ATTRwt-CM is approximately five years from diagnosis [2677]. The disease may be associated with sudden deaths among the elderly [78].

Cardiac nuclear scintigraphy using bone avid radiotracers is the sole imaging method capable of accurately diagnosing ATTR-CM without the requirement of invasive cardiac biopsy. This modality becomes relevant when serum and urine tests for AL amyloidosis yield negative results [2231102124125].

Three technetium ^{99 m}(Tc)-labeled phosphate-based bone avid scan radiopharmaceuticals are useful to detect cardiac ATTR, including hydroxymethylene diphosphonate (HMDP), pyrophosphate (PYP) and DPD. Overall, their diagnostic accuracy appears equivalent [126]. Tc-99 m methylene diphosphonate (MDP) is not recommended as its sensitivity is significantly lower compared to the other agents [103127].

Quantification of the intensity of radiotracer uptake by the heart is important in the diagnosis of ATTR-CM using bone scintigraphy. The intensity of retention of bone-avid radiotracers in the heart can be interpreted by semiquantitative visual analysis, by grading myocardial uptake in relation to rib uptake on planar or single-photon emission computed tomography (SPECT) images, and by quantifying radiotracer uptake using the heart-to-contralateral lung (H/CL) ratio [128]. Perugini et al. classified cardiac amyloid uptake based on a simple visual scoring system of the delayed (3h) planar image, in which a grade of 0 means no cardiac uptake, a grade of 1 means mild cardiac uptake (less than in bone), a grade of 2 means cardiac uptake with intensity similar to bone rib uptake, and a grade of 3 means substantial cardiac uptake (with a weak or no signal evident in bone) [129130] (Figure 6).

Diagnostic criteria for positive planar scintigraphy include a Perugini score ≥2 [2231102124125], and/or a heart/contralateral (HCL) chest ratio ≥1.5 on a 1-h scan or >1.3 on a 3h scan [125]. Single-photon emission computed tomography enables a more accurate assessment of tracer uptake in the myocardium and blood pool, and it is recommended by all national and international societies [2231102124125]. Optimal methods to quantitate SPECT studies (with and without CT) are currently under investigation [131].

In a large multicentre study involving 1,217 patients, false positives almost exclusively resulted from uptake by AL amyloidosis [126]. Bone scintigraphy with a Perugini grade of two or three of myocardial uptake showed a high sensitivity of >99% for ATTR-CM but a lower specificity of 82–86%, given that a grade of 1 or 2 can be observed in patients with AL-CM [99]. However, if urine and serum tests are negative for AL amyloidosis, the specificity of the test increases to 100%. But the images obtained with the different agents are not identical, with HMDP seeming to have a very low false positive rate [126132133134]. Uptake of amyloid can also be noted in patients with early ATTR-CM as well as with other subtypes of cardiac amyloidosis, such as serum amyloid A and apolipoprotein A1 [99]. In addition, other conditions may cause cardiac uptake on bone avid tracer cardiac scintigraphy or increased extra skeletal accumulation in the region of the heart and/or other soft tissues, causing potential diagnostic pitfalls in ATTR-related amyloidosis [135136137138139] (Supplementary Figure 1).

Currently, in the absence of histological data, ATTR-CM can be confidently diagnosed when a patient presents with a clinical phenotype that is associated with echo or CMR findings suggestive of amyloidosis, grade 2 or 3 tracer uptake in the heart on bone avid tracer scintigraphy, and the absence of detectable monoclonal immunoglobulin in the blood and urine using sensitive assays.

The comparative performance of the different tracers remains unclear as ^{99 m}Tc-DPD and ^{99 m}Tc-HMDP are currently most often used in Europe, and ^{99 m}Tc-PYP is the predominant or exclusive tracer available in the United States, Canada, and Japan [140141].

At present, there is no established value in repeating scans to evaluate disease burden in patients with ATTR-CM. However, the potential benefits of repeating scans have not been extensively studies in the context of current ATTR-CM treatment approaches [111].

Echocardiographic ‘red flags’ for ATTR-CM can aid the early diagnosis of ATTR-CM. In a study with over 5,000 patients aged 55 or older undergoing echo examination, 7% exhibited at least one echo ‘red flag’ [174175]. Among patients with the applied criteria, a multiparametric diagnostic algorithm revealed a 24% prevalence of ATTR-CM, increasing with age [174176]. Patients with HF and unexplained LVH were commonly referred for echo examination, suggesting the echo laboratory may play a crucial role in identifying individuals suspected of having amyloid cardiomyopathy [175176].

The incidental finding of cardiac uptake of tracer on bone scintigraphy procedures performed for non-cardiac reasons may lead to an early diagnosis of previously unsuspected cardiac ATTR. However, it can also be a false positive or even correspond to a clinical situation other than ATTR [99126135136137138139177178179] (Supplementary Figure 1). Thus, the incidental finding must always be interpreted in the appropriate context.

Heart failure and LVH are late manifestations of ATTR-CM. In the absence of any of these conditions, an earlier diagnosis of cardiac ATTRv amyloidosis is clinically possible through the identification of unexpected isolated cardiac arrhythmias, particularly in younger patients (e.g., advanced AV blocks in patients under 50 years), even without clear findings on echo or CMR findings (Figure 10).

Documents issued by national or international societies regarding ATTR cardiac amyloidosis [2231102124125] showed a similar opinion regarding the indication for targeted treatment when there is clear evidence of cardiac disease on echo or CMR. However, gaps remain regarding the indication for treatment in specific scenarios, such as: 1) patients with positive bone scintigraphy in the absence of significant echo or CMR findings; 2) patients with significant cardiac arrhythmias and familial disease, but negative bone scintigraphy and no clear evidence of cardiomyopathy on echo or CMR exams (as shown in Figure 10); and 3) positive cardiac involvement in asymptomatic patients.

A study involving six international amyloid centres and including 118 patients with ATTR-CM (either genetic or wild type) [188] demonstrated that almost one-third of patients without HF symptoms at initial evaluation developed HF after a median follow-up period of 3.7 years. Treatment with TTR stabilizers was associated with less progression to clinical HF and improved survival [188].

AL amyloidosis can be essentially excluded by obtaining a monoclonal protein screen comprising 3 laboratory tests: serum free light chain (sFLC) assay, serum immunofixation electrophoresis (SIFE), and urine immunofixation electrophoresis (UIFE) [192193]. If all tests are normal, AL amyloidosis has been excluded with a negative predictive value of >99% [102194]. Serum/urine protein electrophoresis should not be used to exclude a monoclonal protein given its lower accuracy relative to immunofixation for AL amyloidosis. If any of the above three tests is abnormal, a non-invasive diagnostic pathway is no longer an option, and a biopsy of the involved organ is needed [931].

If AL-CM is ruled out, bone avid tracer scintigraphy can be performed to assess for ATTR-CM. If this shows a grade 2/3, a diagnosis of ATTR-CM can be made, and genetic testing (TTR gene) must follow. If scintigraphy is negative or equivocal (grade 0/1), echo, CMR, and patient history need to be reviewed and referral for tissue biopsy should be considered for patients with ongoing clinical suspicion of cardiac amyloidosis.

Patients with a definitive diagnosis of ATTR-CM should undergo genetic testing (search for TTR gene mutations) to distinguish ATTRv amyloidosis from ATTRwt [2231102124125]. Genetic testing should be performed regardless of age [31102], in concert with genetic counselling. It is worth mentioning that, in a recent study, 5% of individuals with ATTR-CM ≥70 years had ATTRv; among females, the prevalence was 10% [195]. Distinguishing genetic from wild-type disease assists not only with cascade testing of at-risk relatives but may also inform treatment strategy [189].

Endomyocardial (EMB) biopsy should be performed (if another tissue biopsy does not confirm amyloid presence) in the following scenarios [31189]: 1) high clinical suspicion of cardiac amyloidosis in a patient with a monoclonal protein by immunofixation electrophoresis and/or an abnormal sFLC K/L ratio; 2) high clinical suspicion for cardiac amyloidosis despite negative or equivocal scintigraphy; or 3) cardiac scintigraphy is unavailable [189].

While rare, EMB may also detect dual pathology of AL and ATTR-CM, further highlighting the importance of pursuing biopsy in the appropriate clinical context. Since cardiac amyloidosis is a diffuse process, the sensitivity and specificity of EMB approach 100% in both cases with adequate samples. However, in very early disease, amyloid deposition may be patchy, although this situation seems to be quite rare. If EMB is not possible, alternatives include fat pad biopsy (although, due to the low sensitivity, if it is negative it is not sufficient to exclude cardiac amyloidosis), renal biopsy (in patients with suspected renal amyloidosis), bone marrow biopsy, or, eventually, a biopsy of the lip, skin or digestive tract [125].

Once amyloidosis is identified on tissue biopsy, the tissue should then be typed with either mass spectrometry or immunohistochemistry to further determine the subtype [102].

Managing HF in patients with cardiac amyloidosis is challenging because most drugs commonly used in patients with HF are not indicated or may have risks in patients with cardiac amyloidosis. Thus, effective treatment and management are more difficult, requiring unique considerations in treatment planning.

Congestion is a significant issue in patients with ATTR-CM and HF, and diuretics play a fundamental role in its control. High doses are often required, particularly in patients with severe diastolic or systolic dysfunction [209]. However, diuretic treatment should be administrated carefully to prevent excessive diuresis, which can lead to a significant decrease in preload with worsening renal function. Typically, a loop diuretic (e.g., furosemide or torsemide) is combined with a mineralocorticoid receptor antagonist (e.g., spironolactone, eplerenone). Caution must be taken when using diuretics in patients with autonomic dysfunction due to the risk of orthostatic hypotension.

In general, restrictive cardiomyopathies, including amyloid cardiomyopathy, have limited tolerance to beta-blockers. This class of drugs can often cause low cardiac output, fatigue, conduction disturbances, hypotension, and even syncope in conditions with a restrictive physiology like ATTR-CM where heart rate significantly affects cardiac output [210]. Conversely, a notable clinical suspicion for possible cardiac amyloidosis is the development of profound hypotension and fatigue following the initiation of beta-blockers [211]. Similarly, non-dihydropyridine calcium channel blockers are poorly tolerated due to their negative inotropic, chronotropic, and dromotropic effects.

There is currently no supporting evidence for the use of these drugs in patients with cardiac amyloidosis. Additionally, it should be noted that the tendency to hypotension can be exacerbated in the presence of autonomic dysfunction.

Traditionally, digoxin has been contraindicated in cardiac amyloidosis due to its potential to bind to amyloid fibrils, resulting in increased toxicity. However, a recent study concluded that if digoxin is considered necessary for rate control in patients with AF, it can be cautiously used in cardiac amyloidosis [212]. According to the study’s findings the authors suggested using low doses (0.125 mg/day or lower) while closely monitoring digoxin concentrations, renal function, and electrolytes levels.

SGLT2is (also called ‘Gliflozins’) have a class I indication for patients with symptomatic HF [213]. In an observational study, the initiation of dapagliflozin was well tolerated in patients with ATTR-CM who were already receiving tafamidis treatment [214]. However, the efficacy of SGLT2is therapy in ATTR-CM patients requires further investigation through randomized controlled trials as the major trials involving SGLT2is excluded patients with known cardiac amyloid.

Atrial arrhythmias, particularly AF, are commonly observed in cardiac amyloidosis, due to atrial dilatation and atrial wall infiltration with amyloid. Achieving rhythm and rate control can be challenging in these patients, as there are limited pharmacological options. Amiodarone is frequently prescribed and generally well tolerated [210]. Other drugs used in clinical practice include sotalol and dofetilide. For appropriately selected patients, catheter ablation for AF may be a viable strategy, yielding the best outcomes when performed earlier in the disease progression [215216]. However, further data are needed to assess the efficacy of catheter ablation in ATTR-CM patients with AF. Ventricular arrhythmias are also common in the disease and amiodarone may be considered for pharmacological treatment [210]. Sustained ventricular tachycardias may pose a risk for sudden cardiac death [210].

Intracardiac thrombosis is frequent in cardiac amyloidosis, even in the presence of sinus rhythm and preserved systolic function, likely due to poor atrial function [217]. This has a significant impact on mortality [217]. In the presence of atrial mechanical dysfunction, anticoagulation may be considered, even for patients with sinus rhythm [218219]. The decision for anticoagulation should not be solely based on the CHA₂DS₂-VASc score, since no association was found between this score and the presence of left atrial appendage thrombus on transoesophageal echocardiogram (TEE) and embolic events [220221222]. Moreover, when cardioversion for atrial arrhythmias is planned, TEE should be performed to rule out left atrial thrombi even among patients who receive an adequate anticoagulation regime [219].

Anticoagulation with either warfarin or novel oral anticoagulants is generally safe for patients with cardiac amyloidosis [209222]. However, in cases where there is a prohibitive bleeding risk, consideration may be given to left atrial appendage closure devices, as they may reduce bleeding complications and ischemic cerebrovascular events without increasing the rate of early or mid-term complications [223].

Conduction disturbances and bradyarrhythmia are highly prevalent in cardiac amyloidosis and are associated with a high rate of pacemaker (PM) implantation during follow-up [224]. In patients with ATTRv amyloidosis and predominant neurologic involvement, cardiac involvement typically presents as arrhythmias and conduction disorders due to dysautonomia and amyloid deposition in the heart. Cardiomyopathy presenting as HF is less common in early forms of familial amyloid polyneuropathy. However, managing asymptomatic patients with evidence of conduction disorders remains challenging, and the follow-up should include serial ECG and Holter recordings [225226227]. In patients with ATTR-CM requiring pacing, biventricular pacing should be considered to minimize deleterious remodeling and progressive HF associated with higher burden of right ventricular pacing [228]. Implantable cardioverter defibrillators (ICDs) are recommended in cases of aborted sudden cardiac death (SCD) with an expected survival >1 year or significant ventricular arrhythmias [102]. However, the benefit of ICDs for primary prevention of SCD in patients with ATTR-CM is uncertain [229], as no clinical predictors of appropriate ICD therapy have been identified [230]. Guidelines differ in their recommendations for primary prevention of SCD: the 2023 American guidelines recommend an individual decision [189] and the European Society of Cardiology refers that it is usually not recommended [31].

Autonomic dysfunction with orthostatic hypotension can be managed using medications that act as norepinephrine replacers such as midodrine (2.5 to 10 mg oral, t.i.d) or droxidopa (100 to 600 mg oral, t.i.d.). Non-specific treatments like fludrocortisone (0.1 to 0.2 mg once daily) or octreotide (12.5–25 mcg, up to 1 to 3 times/day, subcutaneous injection) can also be considered. However, these interventions may be poorly tolerated in patients with HF due to the potential for fluid retention [189]. An alternative option without the risk of fluid retention is pyridostigmine, and anticholinergic medication for orthostatic hypotension [231]. Nonpharmacological interventions such as wearing compression stockings, discontinuing hypotensive medications (i.e., tansulosin, carvedilol, clonidine, tizanidine, nitrates, sildenafil citrate and tricyclic antidepressants), and increasing the daily intake of water can also be beneficial.

The correction of valve defects (mitral/tricuspid regurgitation, aortic stenosis), when indicated, makes part of the supportive therapy that should be offered to ATTR-CM patients. The specific issue of aortic stenosis has been addressed previously.

In specific cases of ATTR-CM and refractory HF symptoms, advanced therapies and heart transplantation (HT), may be considered as an option [232]. The identification of suitable candidates for advanced HF therapies requires a comprehensive evaluation of various factors and include clinical assessment, laboratory testing, and imaging studies. This ensures that the patients who are most likely to benefit from these therapies are selected. Frailty is an important consideration that can impact outcomes and should be considered [233].

The use of durable LV assist devices as a bridge-to-transplant or as destination therapy [234235] is a viable option for highly selected patients with cardiac amyloidosis, particularly in those without significant right ventricular dysfunction prior to implantation. Reasonable outcomes have been observed in such cases [235].

Certain contraindications exist for HT, including the extent of extracardiac involvement and its potential impact on post-transplant morbidity and mortality [189]. In the context of ATTR-CM, extracardiac involvement such as gastrointestinal (GI) involvement and autonomic neuropathy may be factors that contraindicate HT. Gastrointestinal involvement can lead to malnutrition, increasing the risk of infection and impairing wound healing. Additionally, pre-existing disabling neuropathy will not improve after HT and can significantly impair rehabilitation efforts and quality of life [189]. For ATTRwt-CM specifically, some centres may consider age of 70 or older as a potential barrier if significant extracardiac organ involvement is present. For ATTRv amyloidosis-CM, heart-liver transplantation has traditionally been considered in patients at risk of neuropathy since neuropathy can progress even after HT alone. However, currently, HT alone may be an option as TTR-specific therapy, such as tafamidis or a silencing agent (in patients with ATTRv-CM), can be prescribed post-transplant if coexisting amyloidosis-related polyneuropathy is present [236].

In the prespecified cardiac subpopulation comprising patients with a baseline left ventricular wall thickness ≥13 mm and no history of hypertension or aortic valve disease. Patisiran reduced mean LV wall thickness and LV mass, increased the LV end-diastolic volume, improved LV GLS, and showed lower values of NT-proBNP, compared with placebo. These findings suggested the drug might halt or even reverse the progression of ATTR-CM [249250]. Additionally, a small study in patients with ATTRv amyloidosis, demonstrated that patisiran led to significant reduction in ECV as measured by CMR, along with clinical, functional, and scintigraphy benefits [251]. Recently, in the APOLLO-B trial, patisiran demonstrated a statistically significant benefit in functional capacity (measured by the six-minute walk test, as well as improvements in health status and quality of life, compared to placebo, in patients with ATTR-CM regardless of whether hereditary or wild type [252].

Other therapies have been attempted in ATTR-CM, such as the use of TTR degraders with the combination of doxycycline and tauroursodeoxycholic acid (TUDCA) [266], or are being studied, including anti-monoclonal antibody targeting TTR deposits in patients with TTR cardiac amyloidosis (NCT04360434). In a phase I study, the safety and pharmacokinetics of ascending doses of the anti-monoclonal antibody NI006 (ALXN2220) for the depletion of TTR deposits (i.e., ATTR depleter) were assessed in patients with ATTRv-CM or ATTRwt-CM and chronic HF [267]. Cardiac imaging studies were also undertaken. The use of NI006 was not associated with drug-related serious adverse events. Cardiac tracer uptake on scintigraphy and ECV on CMR were reduced and median NT-proBNP and troponin T levels were also reduced [267].

Light or moderate-intensity exercises can help alleviate pain and fatigue in amyloidosis patients. Sleep therapy may be beneficial for those experiencing sleep-related fatigue.

Dietary guidelines include a reduced-salt diet in HF patients, small frequent meals, and refraining from coffee, alcohol, and spices, namely in the case of bowel symptoms. A balanced diet and adequate fluid intake are important.

The support of a physiotherapist and a nutritionist within a multidisciplinary team management is crucial in managing amyloidosis and is typically available at specialized amyloidosis centres.

Patients often inquire about the potential benefit of ‘natural products’ such as green tea for amyloidosis. Some studies suggest that polyphenols in tea, consumed in high quantities, may help prevent amyloid protein aggregation and deposition, potentially impacting positively the disease [268269270]. In ATTR-CM patients the treatment with green tea extract for nine months reduced left ventricular wall mass and thickness in ATTR-CM patients [268]. However, a single-centre retrospective study showed no survival benefit in patients who received a 675 mg daily dose of EGCG (Epigallocatechin-3-gallate, a polyphenolic natural compound abundant in green tea) compared to those receiving symptomatic treatment alone [271].

Limited date is available on COVID-19 in patients with amyloidosis. Nonetheless, these patients are at higher risk for COVID-19 complications and mortality due to age, HF, other organ dysfunction, and comorbidities [272273].

Although specific recommendations for amyloidosis patients are lacking, general indications form the World Health Organization’s should be applied, and vaccination is generally recommended unless contraindicated [274]. Support organizations like The UK National Amyloidosis Centre and the Australian Amyloidosis Network provide updated information and protective measures against COVID-19 for amyloidosis patients [275].