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J Am Acad Dermatol 2002 Nov;47(5):795

Female pattern hair loss.


In this issue of the Journal (pages 733-9), Shum et al1 describe 4 female patients with increased androgens whose central scalp hair loss responded to finasteride. This is an important observation and one that highlights why the term androgenetic or androgenic alopecia, as used to describe the hereditary pattern balding of men, should be replaced with the term female pattern hair loss when applied to women.2 It is clear that only a small but distinct subset of women with central scalp pattern hair loss, such as the patients presented in the report by Shum et al, has signs of hyperandrogenism such as acne, hirsutism, and irregular periods with or without elevation of serum androgens. Therefore these women may have hair loss resulting from a different mechanism and may respond differently to treatments targeted at androgen blockade than women with a similar type of hair loss but without evidence of hyperandrogenism. Certainly these women with hyperandrogenemia may develop, in contradistinction to those without hyperandrogenemia, a Hamilton pattern of hair loss (male pattern baldness). Many of these women may, on more careful evaluation, have polycystic ovarian syndrome.

It is not surprising that a 5-reductase inhibitor such as finasteride, which has documented efficacy in men with androgenetic alopecia3,4 and has been shown to advantageously affect hirsutism,5,6 may cause hair growth in women with female pattern hair loss and hyperandrogenism. The fact that finasteride has not previously been shown to induce hair growth in postmenopausal women with “androgenetic alopecia”7 speaks for (1) adoption of different terminology for this type of hair loss in women and (2) separate evaluation of the different subgroups of women with female pattern hair loss as recently described,2 that is, early onset with and without hyperandrogenemia and late onset/postmenopausal with and without hyperandrogenemia. We should not be too quick to rule out efficacy of a potential therapeutic agent in all women with female pattern hair loss without first testing it in all the various subsets of women.

Clearly, finasteride may be an effective treatment for women with early-onset female pattern hair loss and hyperandrogenemia, but definitive results would require a large, well-controlled trial. Such a trial would likely necessitate inclusion of a “placebo” run-in phase with an oral contraceptive, both to protect these women of child-bearing potential from getting pregnant while taking a drug known to cause genital abnormalities in male fetuses and to rule out any effect from the oral contraceptive alone on female pattern hair loss (a study that needs to be conducted in any case). Anecdotal reports, such as that presented by Shum et al,1 should ignite interest in evaluating finasteride and other 5-reductase inhibitors, either type II or combination type I/II, in women with female pattern hair loss, a group of patients whose current treatment options are extremely limited.


Eur J Dermatol 2002 May-Jun;12(3):236-9

HLA class II alleles in patients with alopecia areata.


Our purpose was to determine which HLA class II alleles are associated with Turkish alopecia areata patients. Also we investigated whether there was a relationship between the age of onset and severity of disease and HLA alleles or not. Sixty-five patients with alopecia areata were included in this study, and 50 healthy transplant donors were used as a control group. The total group of alopecia areata patients as well as various subgroups according to scalp hair loss were compared to the control group. HLA DNA typing was performed by polymerase chain reaction/sequence specific primer method. The frequency of DQB1*03 allele was 86.1% in all patients compared to 62.0% in controls (P = 0.005). While the frequency of DQB1*03 was significantly increased, the frequency of DRB1*03 was decreased in the all patients group (4.6% versus 22.0%, P = 0.01). In the group of scalp hair loss less than 25%; the frequency of DRB1*03 was decreased (3.2%, P = 0.02). The group of patients with 25-75% scalp hair loss was compared to control group; the frequencies of DRB1*04 (66.7% versus 28.0%, P = 0.02) was increased. When the alopecia totalis, alopecia universalis or alopecia totalis/alopecia universalis group was compared to control group; DQB1*03 was associated with an increased frequency in this group versus control group (90.9%, P = 0.03). There were no significant differences for the other DQ alleles and the DR alleles tested in the patients and in the controls. When patients with early onset were compared to patients with late onset; no significant allele differences were found. Our findings suggested that DQB1*03 allele is a marker for general susceptibility to alopecia areata and may also serve as special genetic marker for susceptibility for the severe form of alopecia areata in our population. However, this association is not related to age at onset of the disease.


Eur J Cancer Care (Engl) 2001 Sep;10(3):147-63

Hair and cancer chemotherapy: consequences and nursing care--a literature study.


Hair is a body appendage that throughout history has been a symbol of the social, cultural and political climate, in addition to connoting religious affiliation. Hair loss on the other hand has been associated with a loss of attractiveness, individuality, a state of disgrace and illness, in addition to the ageing process, death and a loss of sexuality. One of the most common side-effects of chemotherapy is hair loss (alopecia). Alopecia can range from sporadic thinning of the hair to complete baldness. Several factors may contribute to the severity of hair loss including drug, dose and schedule as well as hair care practices. Prevention of alopecia has been a focus in the medical and nursing literature since the late 1960s. Mechanical, physical and biological measures have been used with varying success. The goal of prevention is primarily the reduction of patient distress caused by chemotherapy-induced alopecia. Patient reactions to alopecia vary and may be dependent on the individual importance of hair, prognosis, degree of expected hair loss, the amount of information and preparation given, and physical and psychological coping mechanisms. Nurses play an important role in assisting the patient to cope with alopecia by giving the needed information and teaching self-care strategies to minimize alopecia, cope with alopecia, and protect the skin and eyes following alopecia. These interventions are aimed at helping the patient move through a potentially devastating experience to a renewed sense of well-being.


Am J Pathol. 2003 Mar;162(3):803-14.

Stress inhibits hair growth in mice by induction of premature catagen development and deleterious perifollicular inflammatory events via neuropeptide substance P-dependent pathways.


It has been much disputed whether or not stress can cause hair loss (telogen effluvium) in a clinically relevant manner. Despite the paramount psychosocial importance of hair in human society, this central, yet enigmatic and controversial problem of clinically applied stress research has not been systematically studied in appropriate animal models. We now show that psychoemotional stress indeed alters actual hair follicle (HF) cycling in vivo, ie, prematurely terminates the normal duration of active hair growth (anagen) in mice. Further, inflammatory events deleterious to the HF are present in the HF environment of stressed mice (perifollicular macrophage cluster, excessive mast cell activation). This provides the first solid pathophysiological mechanism for how stress may actually cause telogen effluvium, ie, by hair cycle manipulation and neuroimmunological events that combine to terminate anagen. Furthermore, we show that most of these hair growth-inhibitory effects of stress can be reproduced by the proteotypic stress-related neuropeptide substance P in nonstressed mice, and can be counteracted effectively by co-administration of a specific substance P receptor antagonist in stressed mice. This offers the first convincing rationale how stress-induced hair loss in men may be pharmacologically managed effectively.


Being such a complex biological process, hair growth biology is still a work in progress. Noetheless, several therapeutic methods, including drugs, surgery, and suppelements have been in use to help those who attempt to restore their hair. None of these approaches are perfect due to the diversity in the causes underlying hair loss. Also, most of chemical drugs and hair transplantation surgeries are accompanied by undesirable side effects.

DreamPharm offers Hair Million to address hair loss problems. Numerous anecdotal cases have demonstrated that this herbal formula based on authentic Chinese herbs actually improves the age-related hair thinning and hair loss among a significant fraction of people who take it regularly. We still do not understand the mechanisms of action as to how Hair Million works to stop hair loss and promote hair growth, despite all the positive anecdotal observations. Neither scientific research nor placebo controlled clinical analysis has been conducted because it will cost dearly. Lack of scientific/clinical research is quite common in herbal arena. Just because science hasn't scrutinized we should not stop taking daily food and herbal supplements altogether: our life must go on until we have better understandings of food and herb. There are two merits in this hair restoration herbal formula: Firstly, Hair Million is relatively inexpensive, and secondly, it is made of edible herbs that are known to be safe when consumed in regular quantities. For scientifically proven prescription medication, check Buy Propecia Online.








Related Web resources:


  • What is hair?
  • Curly Hair
  • Biology of hair growth and development.
  • The phenomenon of hair loss.
  • Methods and treatments for hair loss and baldness.
  • Drugs and hair transplantation surgery for hair loss and baldness.
  • Hair loss linked to other health problems.
  • Baldness by choice and fashion.
  • Alopecia info.
  • Alopecia treatment info.
  • Alopecia treatment info.
  • Hair care info.
  • Hair loss and alopecia research articles: abstracts and source links.



    DHEA has been suggested to provide numerous potential benefits. DHEA (or dehydroepiandrosterone) is converted into androgens (male hormones) or estrogens (female hormones) in the cells.





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