Age related ED: How to Prevent it and Manage it

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madman

Super Moderator
Looking at some of the more recent studies it has been stated that:

*No evidence has emerged concerning the development of any form of dependence or tolerance with the chronic use of PDE5 inhibitors.




Aging-related erectile dysfunction—a potential mechanism to halt or delay its onset
Monica G. Ferrini, Nestor F. Gonzalez-Cadavid, Jacob Rajfer

Abstract:

Erectile dysfunction (ED) will visit every man at some time in his life. The age at which that knock on the door is heard is totally dependent on one’s genetics as well as other extrinsic factors. Unlike guests who come for a visit and then leave, once ED shows up it tends to hang around forever. To add insult to injury, the longer ED hangs around, the worse it will get. It is estimated that by the time a man is in his 40's, he has about a 40% chance of having some form of ED, and this prevalence increases about 10% per decade thereafter. This suggests that the aging-related process that leads to ED begins early in life. It turns out that the most common cause of ED, regardless of the patient’s age, is due to a problem with the vascular system of the penis. However, this specific aging-related vascular problem is not caused by arterial disease but due to dysfunction and/or loss of the corporal smooth muscle cells (SMC), the main constituent of the corporal sinusoids. As one gets older, these SMC continue to degrade and disappear. When approximately 15% of these cells have been impacted, it results in an inability of the corporal tissue to retain and/or prevent the blood from “leaking” out of the corporal sinusoids into the systemic veins. However, the corporal SMC themselves begin to combat this aging process by expressing the inducible nitric oxide synthase (iNOS) enzyme to make nitric oxide (NO) in an attempt to quench the high intracellular oxidative stress responsible for the SMC apoptosis. When this iNOS pathway is then pharmacologically upregulated, the reversal of these aging-related changes in the corpora with correction of the venous leakage is observed. Since we believe that aging-related ED is pathologically the same disorder as essential hypertension, the development of a therapeutic regimen that can halt, delay or possibly reverse the cellular processes that lead to aging-related ED should also be applicable to those patients diagnosed with essential hypertension.




Introduction

For many a man, their potency defines their joie de vivre. It is well established that men who engage in sexual activity are happier (1), live longer (2), are less depressed, and definitely do experience a better quality of life (3-7). It is generally assumed in today’s society which values youth over old age that it is only the elderly who are at risk of losing their potency; however, recent data suggest that this may be a gross misconception (8,9) and could explain why some of us believe that “grumpy old men” seem to be getting younger and younger. Thus, it seems reasonable to ask the question: what can medicine do to prevent or, more reasonably, delay the onset of impotency or erectile dysfunction (ED) in the hopes that this affliction which so defines many a man does not raise its ugly head until one very ends? Like most quests in medicine, the solution to an affliction usually lies in an understanding of its cause. Along with this reasoning, this review will highlight what is currently known about the epidemiology, physiology, and pathophysiology of ED, and from this knowledge, we will try to identify therapeutic options that could lead to a potential solution to our aforementioned million dollar question. Since the penis is considered the window for what is ongoing within the cardiovascular system and since we believe that both aging-related ED and essential hypertension are pathologically the same disorder, we hypothesize that any treatment that is effective in either preventing and/or delaying the onset of aging-related ED should also be effective in the same manner against essential hypertension.

Every man, if he lives long enough, is destined to develop what Masters and Johnson called aging-related impotence (10) which we now term aging-related erectile dysfunction (ARED). This is exemplified by the data from the Massachusetts Male Aging Study (MMAS) which indicated that about 40% of men in their 40’s will have some form of ED and this prevalence will increase about 10% per decade such that a man in his 50’s has about a 50% chance of having ED while a man in his 60’s has about a 60% chance of having ED, etc. (11).
These prevalence data from the MMAS as well as others (8)intuitively suggest that the physiological processes that cause 40% of men in their 40's to have some form of ED must have begun at an earlier age. If this intuition is indeed correct, it would explain why we physicians do see in our office some men in their 20's and 30's complaining of ED that ultimately turns out to be due to a primary physiological and not a primarily psychological cause.


Pathophysiology of ARED

ED is defined as the inability of a man to either attain and/ or maintain his erection long enough to complete the sexual act (12). It turns out that the development of an erection is a simple sequential two-step mechanical event: the initial step is for fluid (blood) to be transported into an expanding receptacle (the cavernosal sinusoids) which results in the enlargement and rigidity of the penis. The second event involves the maintenance of that enlargement and rigidity, a process that is dependent on the ability of the corporal bodies to prevent the blood that has come into the expanded sinusoids from then “leaking” out through the veins draining these sinusoids before the sexual act is completed. The inflow of blood into the corporal sinusoids via the cavernosal arteries that are located within the corporal bodies themselves, as well as the expansion of the corporal sinusoids which provides a space into which this increasing blood will pool is primarily dependent on the relaxation of the smooth muscle located both within the arterial system and corporal sinusoids, respectively (13,14). When the blood from the arterial system pools into the expanding corporal sinusoids, the intra-corporeal pressure will begin to rise and at a certain level the intra-corporeal pressure will passively compress and shut the venous channels that egress from those corporal bodies under the less distensible tunica albuginea (Figure 1). It is this compression of the veins by the attainment of an intra-corporeal pressure that is high enough to accomplish this that prevents the sinusoidal blood from leaking out into the venous channels (15,16). When arterial inflow is low (trouble attaining the erection), we term this arterial insufficiency and when the venous outflow is too high (trouble maintaining the erection), we term this cavernosal Veno-occlusive dysfunction (CVOD) or simply “venous leakage”. Both arterial insufficiency and CVOD are the two forms of vasculogenic dysfunction and either one by itself or a combination of both can lead to symptomatic ED.


Etiology of ARED

All patients with ED will have as their primary cause either a psychological or a physiological reason. All forms of physiological ED other than what is due to a structural anomaly such as a chordee can be relegated to either a vasculogenic, neurogenic, and/or a hormonal cause. When men of various ages from 18 to 80 years are studied to determine the cause of their ED, the most common etiology identified regardless of age is vasculogenic, specifically CVOD (17,18). This high prevalence of CVOD, when compared to that of arterial disease (or defective inflow of blood into the penis), is most striking in the younger population i.e., in men younger than 40 years of age (18,19). However, once middle age begins to set in and the onset of hypertension and diabetes mellitus and other middle-age maladies become more prevalent, the incidence of arterial disease as a cause of ED begins to follow suit (20).

Nevertheless, despite this increase in the incidence of arterial disease as men age, CVOD or venous leakage can still be identified in about 67% to 75% of men complaining of ED, regardless of whether they are young, middle-aged, or elderly (17).

For those of us who specialize in seeing men with ED, particularly men younger than 50 years of age, the most common first symptomatic complaint of their ED is that they are either unable to keep their erection lasting as long as they previously could or that they simply “lost” their erection during the sexual act. These complaints would suggest, in the Oslerian way of listening to what the patient is saying, that the patient was telling us that he was “losing the blood from his erect penis” i.e., heralding the onset of symptomatic venous leakage or CVOD. So why does this venous leakage seem to signal the onset of ED in most men and why does it begin at an early age in some men? As mentioned earlier, the ability to attain an erection is due to the increase in blood going into the corporal sinusoids via the arterial tree in tandem with the pooling of this blood within the corporal sinusoids. The increase in blood flow via the arterial vessels as well as the increase in the size of corporal sinusoids is due to the relaxation of the smooth muscle within both the arterial vessels and the corporal sinusoids, a process that is regulated by the release of nitric oxide (NO) (21) synthesized by its enzyme, the neuronal isoform of nitric oxide synthase (nNOS), that is actually located outside the SMC within the terminal axons of the nerve (Figure 2) innervating this corporal smooth muscle (22). The NO from nNOS rapidly enters the SMC and initiates the process of smooth muscle relaxation.

As long as the blood that enters the sinusoidal spaces can be retained within the sinusoids to allow the attainment of an intra-corporeal pressure that is high enough to compress the veins exiting the corporal bodies, the erection itself will be maintained.
The length of time a man can keep his erection without losing it before the completion of the sexual act is then dependent on how long the corporal smooth muscle can be maintained in its relaxed state. If the corporal smooth muscle tires easily or if there are not enough SMC functioning normally within the sinusoids to achieve that high intra-corporeal pressure necessary to compress those egressing veins, the sinusoidal blood will “leak out” and the erection will be “lost”. It is estimated that one only needs to lose approximately 15% of the function of the corporal smooth muscle mass for symptomatic venous leakage to occur (23). Based on our own observations with dynamic infusion cavernosometry over the past 30 years (17,20) in tandem with the known anatomical relationship between the cavernosal artery and the corporal sinusoids (Figure 1), the intra-corporeal pressure that is required to compress the veins exiting the corpora and maintain one’s erection is probably somewhere around the mean arterial pressure of that individual.

As men age, it is recognized that there is an aging-dependent decrease in the amount of the functioning corporal smooth muscle. The mechanism(s) underlying this aging-related loss of the normal smooth muscle within the corporal bodies is believed to be due mainly to an apoptotic process that is primarily triggered by oxidative stress (24). When about 15% of the functioning corporal smooth muscle mass has been impacted, it can lead to symptomatic ED and this theoretically can occur at any age since it is believed the apoptotic process simply due to the aging process is most likely genetically determined in each individual. Support for the concept that this aging-related apoptotic process and subsequent dysfunction of the corporal smooth muscle can and does occur at an early age, is based on the clinical observation that the refractory period of the penis, that time period between the attainment of two subsequent and separate erectile episodes, begins to increase in most men sometime during their 20’s and continues to progress with the aging process. By inference, it is safe to state that when the patient (who has normal arterial inflow) “recognizes” the onset of the inability to maintain his erection, it most likely indicates that the aging process within the corpora has already begun.

Additional clinical evidence to support the belief that the aging-related apoptotic process of the corporal smooth muscle begins at an age much earlier than when symptomatic ED occurs lies in the response of young potent men to the ingestion of PDE5 inhibitors used for treating ED.
By inhibiting phosphodiesterase, PDE5 inhibitors enhance the relaxation of the corporal smooth muscle by preventing the breakdown of cGMP within the smooth muscle cells (25) and as a result, this should theoretically allow one to maintain his erection for longer periods of time. cGMP itself is formed within the smooth muscle cell from guanosine triphosphate (GTP) by the enzyme, guanylyl cyclase (26) which is the enzyme that is targeted by NO to begin the production of cGMP. In the penis, the NO that initiates the erectile response is formed from the nNOS enzyme located within the axons of the erectile nerves which is located outside its target, the corporal smooth muscle cells. When young men who are documented to have a normal erectile function are then given oral PDE5 inhibitors, the only observed outcome in these “normal men” is a decrease in their refractory period (27,28) without any significant effect on the rigidity of their erection as measured by the IIEF (international index of erectile function) score (29). Therefore, the reported enhancement of the erectile response to oral PDE5 inhibitors in young men who claim to have normal erectile function would theoretically only occur in those men whose corporal smooth muscle function has already begun to deteriorate.

In fact, it is safe to state that most men who respond to these PDE5 inhibitors, if they live long enough, will at some time later on in their life ultimately fail to respond to these drugs (30,31). Logic then dictates that when this lack of responsiveness occurs and barring any loss of arterial inflow, it could only be due to either (I) progression of the process within the penile tissues that are causing the ED or (II) tachyphylaxis of the PDE5 inhibitor. Since it has been demonstrated unequivocally that these PDE5 inhibitors do not undergo tachyphylaxis (32,33), one can only conclude that for those men who are suffering from ARED the subsequent diminution in their response to these PDE5 inhibitors would have to be by default the progression of the aging-related processes, in particular, the SMC apoptosis that continues to forge ahead on as one age. Once the PDE5 inhibitors become incapable at its highest dose of inducing sufficient tumescence to allow sexual activity to occur where it was previously able to do so, it merely identifies the time has been reached when either the remaining functioning corporal smooth muscle is incapable via the oral route of drug administration of achieving sufficient relaxation to allow the attainment of an intra-corporeal pressure high enough to compress the subtunical veins (increasing venous leakage) or there has been a concomitant decrease in the inflow of blood into the penis which is incapable of providing enough blood to the corporal sinusoids (arteriogenic dysfunction) to allow for any veno-occlusion to occur or it could be due to a little bit of both of these processes. Since an erection is simply a mechanical event requiring a dynamic balance between inflow and outflow of blood within the corporal sinusoids, the determination of whether one or both processes are functioning normally in an individual patient requires an individual evaluation of each of these processes (17,20).

Within the last decade, it was observed in the laboratory that when this aging dependent apoptosis of the corporal smooth muscle occurred, the corporal tissues themselves responded to the related causative oxidative stress by increasing the production of NO within the SMC itself (34) via a process that is different from the NO that is released into the SMC from the terminal axons of the erectile nerves by the nNOS enzyme (Figure 2). This NO that is synthesized within the cytosol of the SMC is produced by another NOS isoform called inducible NOS (iNOS) which is one of three NO producing enzymes in the body. iNOS is normally produced only in the macrophages and Kupffer cells (35) and under the appropriate stimulus, can produce high local levels of NO. Interestingly, these high intracellular levels of NO produced by iNOS have been shown in some systems and tissues to be both noxious, inducing apoptosis, as well as protective, by being antiapoptotic (36,37). However, with respect to the corporal smooth muscle undergoing its aging-related apoptosis, laboratory data suggest that the SMC of the corpora begins the process of expressing iNOS, which produces NO within the cell itself and this appears to be an attempt by the SMC itself to combat the oxidative stress associated with the ongoing apoptotic process (38). In theory, this production of NO from iNOS in the aging penis can be viewed as an attempt by the tissue itself to retard or reverse the ongoing deterioration of the corporal smooth muscle. This can be observed in animal models of ED where this anti-apoptotic effect of NO from iNOS has been shown to be enhanced by compounds that either boost iNOS production (39) or inhibit the breakdown of cGMP (40) without any obvious detrimental effects to any other organ systems in these animals. Indeed, when PDE5 inhibitors which inhibit the breakdown of cGMP and therefore complement the effect of NO are given for long periods of time on a daily and continuous basis to aged animals with ED, the aging-related apoptotic process in the corpora seems to be retarded, the corporal smooth muscle cell content within the corporal tissue surprisingly seems to increase and normal corporal veno-occlusion can be achieved (Figure 3) (40).




Conclusions

The most common cause of ED, regardless of the age of the patient, is vasculogenic due to CVOD or venous leakage. Pathologically, this is due to aging-related apoptosis of the corporal SMC similar to what is believed to also occur in the media of the peripheral vasculature. The apoptotic process in the penis appears to begin early in a man’s life and can be first identified by the increase in the refractory period most men will experience usually sometime around their 3rd decade of life. The progression of this increase in the refractory period over time will reach a stage, depending on the patient’s genetics and co-morbidities, where maintenance of the erection becomes problematic, and symptomatic ED is apparent. In response, the SMC begins to fight the oxidative stress and apoptosis associated with these aging-related changes by producing NO from iNOS. Preliminary data suggest that products that upregulate this NO producing pathway and/or pharmacologically release NO, and/or protect its product, cGMP, show promise in halting or reversing the cellular changes associated with this aging process. It remains to be determined whether such therapy will also be found to be effective on similar aging-related changes that occur in the media of the peripheral vasculature.




European Medicines Agency Evaluation of Medicines for Human Use


• Other supportive data


Vernet et al. examined PDE5 expression and cGMP concentrations during 14 days of continuous incubation of human penile corpora cavernosal smooth muscle cells and fibroblasts of the tunica albuginea with tadalafil at concentrations well above the IC50 (concentration of tadalafil inhibiting 50% of PDE5 activity in vitro) and around the Cmax (mean peak plasma concentration in vivo).

*No up-regulation of PDE5 expression or decrease in cGMP concentrations was observed, suggesting that tachyphylaxis, particularly via transcriptional activation, is not likely to occur with clinical use.
 

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Defy Medical TRT clinic doctor
Excellent report again. It's becoming more clear the direction research needs to go in treating and resolving ED. We need some age-reversal of CCSM. Stem cell the future?
 
Excellent report again. It's becoming more clear the direction research needs to go in treating and resolving ED. We need some age-reversal of CCSM. Stem cell the future?
There is some emerging research on stem cell therapy for ED (attached paper)
 

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What an excellent article. Despite my healthy lifestyle, my hypertension began in my late 40's along with low T and ED issues. However, the ED was like the one described in this article: not true venous leakage, but more subtle like the CVOD they describe. Fixing my T problem, addressing my BP and focusing on NO has greatly improved things for me. However, at age 53, I realize which way the battle is headed. Thank god for the PDE-5 inhibitors and hopefully future treatments to come.

Thanks for posting Madman.
 
great posting madmen
Looking at some of the more recent studies it has been stated that:

No evidence has emerged concerning the development of any form of dependence or tolerance with the chronic use of PDE5 inhibitors.


Aging-related erectile dysfunction—potential mechanism to halt or delay its onset
Monica G. Ferrini, Nestor F. Gonzalez-Cadavid, Jacob Rajfer

Abstract:

Erectile dysfunction (ED) will visit every man at some time in his life. The age at when that knock on the door is heard is totally dependent on one’s genetics as well as other extrinsic factors. Unlike guests who come for a visit and then leave, once ED shows up it tends to hang around forever. To add insult to injury, the longer ED hangs around, the worse it will get.
It is estimated that by the time a man is in his 40’s, he has about a 40% chance of having some form of ED, and this prevalence increases about 10% per decade thereafter. This suggests that the aging-related process that leads to ED begins early in life. It turns out that the most common cause of ED, regardless of the patient’s age, is due to a problem with the vascular system of the penis. However, this specific aging-related vascular problem is not caused by arterial disease but due to dysfunction and/or loss of the corporal smooth muscle cells (SMC), the main constituent of the corporal sinusoids. As one gets older, these SMC continue to degrade and disappear. When approximately 15% of these cells have been impacted, it results in an inability of the corporal tissue to retain and/or prevent the blood from “leaking” out of the corporal sinusoids into the systemic veins. However, the corporal SMC themselves begin to combat this aging process by expressing the inducible nitric oxide synthase (iNOS) enzyme to make nitric oxide (NO) in an attempt to quench the high intracellular oxidative stress responsible for the SMC apoptosis. When this iNOS pathway is then pharmacologically upregulated, the reversal of these aging-related changes in the corpora with correction of the venous leakage is observed. Since we believe that aging-related ED is pathologically the same disorder as essential hypertension, the development of a therapeutic regimen that can halt, delay or possibly reverse the cellular processes that lead to aging-related ED should also be applicable to those patients diagnosed with essential hypertension.

Introduction

For many a man, their potency defines their joie de vivre. It is well established that men who engage in sexual activity are happier (1), live longer (2), are less depressed, and definitely do experience a better quality of life (3-7). It is generally assumed in today’s society which values youth over old age that it is only the elderly who are at risk of losing their potency; however, recent data suggest that this may be a gross misconception (8,9) and could explain why some of us believe that “grumpy old men” seem to be getting younger and younger. Thus, it seems reasonable to ask the question: what can medicine do to prevent or, more reasonably, delay the onset of impotency or erectile dysfunction (ED) in the hopes that this affliction which so defines many a man does not raise its ugly head until one very ends? Like most quests in medicine, the solution to an affliction usually lies in an understanding of its cause. Along with this reasoning, this review will highlight what is currently known about the epidemiology, physiology, and pathophysiology of ED, and from this knowledge, we will try to identify therapeutic options that could lead to a potential solution to our aforementioned million dollar question. Since the penis is considered the window for what is ongoing within the cardiovascular system and since we believe that both aging-related ED and essential hypertension are pathologically the same disorder, we hypothesize that any treatment that is effective in either preventing and/or delaying the onset of aging-related ED should also be effective in the same manner against essential hypertension.

Every man, if he lives long enough, is destined to develop what Masters and Johnson called aging-related impotence (10) which we now term aging-related erectile dysfunction (ARED). This is exemplified by the data from the Massachusetts Male Aging Study (MMAS) which indicated that about 40% of men in their 40’s will have some form of ED and this prevalence will increase about 10% per decade such that a man in his 50’s has about a 50% chance of having ED while a man in his 60’s has about a 60% chance of having ED, etc. (11).
These prevalence data from the MMAS as well as others (8)intuitively suggest that the physiological processes that cause 40% of men in their 40’s to have some form of ED must have begun at an earlier age. If this intuition is indeed correct, it would explain why we physicians do see in our office some men in their 20’s and 30’s complaining of ED that ultimately turns out to be due to a primary physiological and not a primarily psychological cause.


Pathophysiology of ARED

ED is defined as the inability of a man to either attain and/ or maintain his erection long enough to complete the sexual act (12). It turns out that the development of an erection is a simple sequential two-step mechanical event: the initial step is for fluid (blood) to be transported into an expanding receptacle (the cavernosal sinusoids) which results in the enlargement and rigidity of the penis. The second event involves the maintenance of that enlargement and rigidity, a process that is dependent on the ability of the corporal bodies to prevent the blood that has come into the expanded sinusoids from then “leaking” out through the veins draining these sinusoids before the sexual act is completed. The inflow of blood into the corporal sinusoids via the cavernosal arteries that are located within the corporal bodies themselves, as well as the expansion of the corporal sinusoids which provides a space into which this increasing blood will pool is primarily dependent on the relaxation of the smooth muscle located both within the arterial system and corporal sinusoids, respectively (13,14). When the blood from the arterial system pools into the expanding corporal sinusoids, the intra-corporeal pressure will begin to rise and at a certain level the intra-corporeal pressure will passively compress shut the venous channels that egress from those corporal bodies under the less distensible tunica albuginea (Figure 1). It is this compression of the veins by the attainment of an intra-corporeal pressure that is high enough to accomplish this that prevents the sinusoidal blood from leaking out into the venous channels (15,16). When arterial inflow is low (trouble attaining the erection), we term this arterial insufficiency and when the venous outflow is too high (trouble maintaining the erection), we term this cavernosal Veno-occlusive dysfunction (CVOD) or simply “venous leakage”. Both arterial insufficiency and CVOD are the two forms of vasculogenic dysfunction and either one by itself or a combination of both can lead to symptomatic ED.


Etiology of ARED

All patients with ED will have as their primary cause either a psychological or a physiological reason. All forms of physiological ED other than what is due to a structural anomaly such as a chordee can be relegated to either a vasculogenic, neurogenic, and/or a hormonal cause. When men of various ages from 18 to 80 years are studied to determine the cause of their ED, the most common etiology identified regardless of age is vasculogenic, specifically CVOD (17,18). This high prevalence of CVOD, when compared to that of arterial disease (or defective inflow of blood into the penis), is most striking in the younger population i.e., in men younger than 40 years of age (18,19). However, once middle age begins to set in and the onset of hypertension and diabetes mellitus, and other middle-age maladies become more prevalent, the incidence of arterial disease as a cause of ED begins to follow suit (20).

Nevertheless, despite this increase in the incidence of arterial disease as men age, CVOD or venous leakage can still be identified in about 67% to 75% of men complaining of ED, regardless of whether they are young, middle-aged, or elderly (17).

For those of us who specialize in seeing men with ED, particularly men younger than 50 years of age, the most common first symptomatic complaint of their ED is that they are either unable to keep their erection lasting as long as they previously could or that they simply “lost” their erection during the sexual act. These complaints would suggest, in the Oslerian way of listening to what the patient is saying, that the patient was telling us that he was “losing the blood from his erect penis” i.e., heralding the onset of symptomatic venous leakage or CVOD. So why does this venous leakage seem to signal the onset of ED in most men and why does it begin at an early age in some men? As mentioned earlier, the ability to attain an erection is due to the increase in blood going into the corporal sinusoids via the arterial tree in tandem with the pooling of this blood within the corporal sinusoids. The increase in blood flow via the arterial vessels as well as the increase in the size of corporal sinusoids is due to the relaxation of the smooth muscle within both the arterial vessels and the corporal sinusoids, a process that is regulated by the release of nitric oxide (NO) (21) synthesized by its enzyme, the neuronal isoform of nitric oxide synthase (nNOS), that is actually located outside the SMC within the terminal axons of the nerve (Figure 2) innervating this corporal smooth muscle (22). The NO from nNOS rapidly enters the SMC and initiates the process of smooth muscle relaxation.

As long as the blood that enters the sinusoidal spaces can be retained within the sinusoids to allow the attainment of an intra-corporeal pressure that is high enough to compress the veins exiting the corporal bodies, the erection itself will be maintained.
The length of time a man can keep his erection without losing it before the completion of the sexual act is then dependent on how long the corporal smooth muscle can be maintained in its relaxed state. If the corporal smooth muscle tires easily or if there are not enough SMC functioning normally within the sinusoids to achieve that high intra-corporeal pressure necessary to compress those egressing veins, the sinusoidal blood will “leak out” and the erection will be “lost”. It is estimated that one only needs to lose approximately 15% of the function of the corporal smooth muscle mass for symptomatic venous leakage to occur (23). Based on our own observations with dynamic infusion cavernosometry over the past 30 years (17,20) in tandem with the known anatomical relationship between the cavernosal artery and the corporal sinusoids (Figure 1), the intra-corporeal pressure that is required to compress the veins exiting the corpora and maintain one’s erection is probably somewhere around the mean arterial pressure of that individual.

As men age, it is recognized that there is an aging dependent decrease in the amount of the functioning corporal smooth muscle. The mechanism(s) underlying this aging-related loss of the normal smooth muscle within the corporal bodies is believed to be due mainly to an apoptotic process that is primarily triggered by oxidative stress (24). When about 15% of the functioning corporal smooth muscle mass has been impacted, it can lead to symptomatic ED and this theoretically can occur at any age since it is believed the apoptotic process simply due to the aging process is most likely genetically determined in each individual. Support for the concept that this aging-related apoptotic process and subsequent dysfunction of the corporal smooth muscle can and does occur at an early age, is based on the clinical observation that the refractory period of the penis, that time period between the attainment of two subsequent and separate erectile episodes, begins to increase in most men sometime during their 20’s and continues to progress with the aging process. By inference, it is safe to state that when the patient (who has normal arterial inflow) “recognizes” the onset of the inability to maintain his erection, it most likely indicates that the aging process within the corpora has already begun.

Additional clinical evidence to support the belief that the aging-related apoptotic process of the corporal smooth muscle begins at an age much earlier than when symptomatic ED occurs lies in the response of young potent men to the ingestion of PDE5 inhibitors used for treating ED.
By inhibiting phosphodiesterase, PDE5 inhibitors enhance the relaxation of the corporal smooth muscle by preventing the breakdown of cGMP within the smooth muscle cells (25) and as a result, this should theoretically allow one to maintain his erection for longer periods of time. cGMP itself is formed within the smooth muscle cell from guanosine triphosphate (GTP) by the enzyme, guanylyl cyclase (26) which is the enzyme that is targeted by NO to begin the production of cGMP. In the penis, the NO that initiates the erectile response is formed from the nNOS enzyme located within the axons of the erectile nerves which is located outside its target, the corporal smooth muscle cells. When young men who are documented to have a normal erectile function are then given oral PDE5 inhibitors, the only observed outcome in these “normal men” is a decrease in their refractory period (27,28) without any significant effect on the rigidity of their erection as measured by the IIEF (international index of erectile function) score (29). Therefore, the reported enhancement of the erectile response to oral PDE5 inhibitors in young men who claim to have normal erectile function would theoretically only occur in those men whose corporal smooth muscle function has already begun to deteriorate.

In fact, it is safe to state that most men who respond to these PDE5 inhibitors, if they live long enough, will at some time later on in their life ultimately fail to respond to these drugs (30,31).
Logic then dictates that when this lack of responsiveness occurs and barring any loss of arterial inflow, it could only be due to either (I) progression of the process within the penile tissues that are causing the ED or (II) tachyphylaxis of the PDE5 inhibitor. Since it has been demonstrated unequivocally that these PDE5 inhibitors do not undergo tachyphylaxis (32,33), one can only conclude that for those men who are suffering from ARED the subsequent diminution in their response to these PDE5 inhibitors would have to be by default the progression of the aging-related processes, in particular, the SMC apoptosis that continues to forge ahead on as one age. Once the PDE5 inhibitors become incapable at its highest dose of inducing sufficient tumescence to allow sexual activity to occur where it was previously able to do so, it merely identifies the time has been reached when either the remaining functioning corporal smooth muscle is incapable via the oral route of drug administration of achieving sufficient relaxation to allow the attainment of an intra-corporeal pressure high enough to compress the subtunical veins (increasing venous leakage) or there has been a concomitant decrease in the inflow of blood into the penis which is incapable of providing enough blood to the corporal sinusoids (arteriogenic dysfunction) to allow for any veno-occlusion to occur or it could be due to a little bit of both of these processes. Since an erection is simply a mechanical event requiring a dynamic balance between inflow and outflow of blood within the corporal sinusoids, the determination of whether one or both processes are functioning normally in an individual patient requires an individual evaluation of each of these processes (17,20).

Within the last decade, it was observed in the laboratory that when this aging dependent apoptosis of the corporal smooth muscle occurred, the corporal tissues themselves responded to the related causative oxidative stress by increasing the production of NO within the SMC itself (34) via a process that is different from the NO that is released into the SMC from the terminal axons of the erectile nerves by the nNOS enzyme (Figure 2). This NO that is synthesized within the cytosol of the SMC is produced by another NOS isoform called inducible NOS (iNOS) which is one of three NO producing enzymes in the body. iNOS is normally produced only in the macrophages and Kupffer cells (35) and under the appropriate stimulus, can produce high local levels of NO. Interestingly, these high intracellular levels of NO produced by iNOS have been shown in some systems and tissues to be both noxious, by inducing apoptosis, as well as protective, by being antiapoptotic (36,37). However, with respect to the corporal smooth muscle undergoing its aging-related apoptosis, laboratory data suggest that the SMC of the corpora begin the process of expressing iNOS, which produces NO within the cell itself and this appears to be an attempt by the SMC itself to combat the oxidative stress associated with the ongoing apoptotic process (38). In theory, this production of NO from iNOS in the aging penis can be viewed as an attempt by the tissue itself to retard or reverse the ongoing deterioration of the corporal smooth muscle. This can be observed in animal models of ED where this anti-apoptotic effect of NO from iNOS has been shown to be enhanced by compounds that either boost iNOS production (39) or inhibit the breakdown of cGMP (40) without any obvious detrimental effects to any other organ systems in these animals. Indeed, when PDE5 inhibitors which inhibit the breakdown of cGMP and therefore complement the effect of NO are given for long periods of time on a daily and continuous basis to aged animals with ED, the aging-related apoptotic process in the corpora seems to be retarded, the corporal smooth muscle cell content within the corporal tissue surprisingly seems to increase and normal corporal veno-occlusion can be achieved (Figure 3) (40).


Conclusions

The most common cause of ED, regardless of the age of the patient, is vasculogenic due to CVOD or venous leakage.
Pathologically, this is due to aging-related apoptosis of the corporal SMC similar to what is believed to also occur in the media of the peripheral vasculature. The apoptotic process in the penis appears to begin early in a man’s life and can be first identified by the increase in the refractory period most men will experience usually sometime around their 3rd decade of life. The progression of this increase in the refractory period over time will reach a stage, depending on the patient’s genetics and co-morbidities, where maintenance of the erection becomes problematic, and symptomatic ED is apparent. In response, the SMC begins to fight the oxidative stress and apoptosis associated with these aging-related changes by producing NO from iNOS. Preliminary data suggest that products that upregulate this NO producing pathway and/or pharmacologically release NO, and/or protect its product, cGMP, show promise in halting or reversing the cellular changes associated with this aging process. It remains to be determined whether such therapy will also be found to be effective on similar aging-related changes that occur in the media of the peripheral vasculature.



European Medicines Agency Evaluation of Medicines for Human Use


• Other supportive data

Vernet et al. examined PDE5 expression and cGMP concentrations during 14 days of continuous
incubation of human penile corpora cavernosal smooth muscle cells and fibroblasts of the tunica albuginea with tadalafil at concentrations well above the IC50 (concentration of tadalafil inhibiting 50% of PDE5 activity in vitro) and around the Cmax (mean peak plasma concentration in vivo).
No up-regulation of PDE5 expression or decrease in cGMP concentrations was observed, suggesting that tachyphylaxis, particularly via transcriptional activation, is not likely to occur with clinical use.

great posting madman, reading this, it sounds like the sooner a man start using PD5E, the better it is! the studies do show no form of dependence from chronic PD5E use, but aren't the studies too short in duration?
 
Circling back to this study, I am wonder if Alpha Blockers (such as Dox) would have a positive effect on the Smooth Muscle Cells (SMC) that seem to be the cause of most venous leakage. My doctor has offered those as a med for my mild BP issues. (Currently on Lisinopril)
 
Circling back to this study, I am wonder if Alpha Blockers (such as Dox) would have a positive effect on the Smooth Muscle Cells (SMC) that seem to be the cause of most venous leakage. My doctor has offered those as a med for my mild BP issues. (Currently on Lisinopril)

 
Circling back to this study, I am wonder if Alpha Blockers (such as Dox) would have a positive effect on the Smooth Muscle Cells (SMC) that seem to be the cause of most venous leakage. My doctor has offered those as a med for my mild BP issues. (Currently on Lisinopril)

EAU Guidelines on Management of Non-Neurogenic Male Lower Urinary Tract Symptoms (LUTS), incl. Benign Prostatic Obstruction (BPO) 2021


5.2 Pharmacological treatment Male Lower Urinary Tract Symptoms

5.2.1 α1-Adrenoceptor antagonists (α1-blockers)

Mechanism of action:
α1-blockers aim to inhibit the effect of endogenously released noradrenaline on smooth muscle cells in the prostate and thereby reduce prostate tone and BOO [139]. However, α1-blockers have little effect on urodynamically determined bladder outlet resistance [140], and treatment-associated improvement of LUTS correlates poorly with obstruction [141]. Thus, other mechanisms of action may also be relevant.

Alpha 1-adrenoceptors located outside the prostate (e.g. urinary bladder and/or spinal cord) and α1-adrenoceptor subtypes (α1B- or α1D-adrenoceptors) may play a role as mediators of effects. Alpha 1-adrenoceptors in blood vessels, other non-prostatic smooth muscle cells, and the central nervous system may mediate adverse events.


Currently available α1-blockers are alfuzosin hydrochloride (alfuzosin); doxazosin mesylate (doxazosin); silodosin; tamsulosin hydrochloride (tamsulosin); terazosin hydrochloride (terazosin); and naftopidil. Alpha 1-blockers exist in different formulations. Although different formulations result in different pharmacokinetic and tolerability profiles, the overall difference in clinical efficacy between the different formulations seems modest.


Tolerability and safety: Tissue distribution, subtype selectivity, and pharmacokinetic profiles of certain formulations may contribute to the tolerability profile of specific drugs. The most frequent adverse events of α1-blockers are asthenia, dizziness, and (orthostatic) hypotension. Vasodilating effects are most pronounced with doxazosin and terazosin and are less common with alfuzosin and tamsulosin [150]. Patients with cardiovascular comorbidity and/or vaso-active co-medication may be susceptible to α1-blocker-induced vasodilatation [151]. In contrast, the frequency of hypotension with the α1A-selective blocker silodosin is comparable with placebo [152]. In a large retrospective cohort analysis of men aged > 66 years treated with α1-blockers the risks of falling (odds ratio [OR] 1.14) and of sustaining a fracture (OR 1.16) was increased, most likely as a result of induced hypotension [153].


An SR concluded that α1-blockers do not adversely affect libido, have a small beneficial effect on erectile function, but can cause abnormal ejaculation [156]. Originally, abnormal ejaculation was thought to be retrograde, but more recent data demonstrate that it is due to a decrease or absence of seminal fluid during ejaculation, with young age being an apparent risk factor. In a recent meta-analysis, ejaculatory dysfunction (EjD) was significantly more common with α1-blockers than with placebo (OR 5.88). In particular, EjD was significantly more commonly related with tamsulosin or silodosin (OR 8.57 and 32.5) than placebo, while both doxazosin and terazosin (OR 0.80 and 1.78) were associated with a low risk of EjD [157]. In the metaregression, the occurrence of EjD was independently associated with the improvement of urinary symptoms and flow rate, suggesting that the more effective the α1-blocker is the greater the incidence of EjD.
 

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